Toll and Congestion Community Objects with Price-Time Priority Queues for Transformed Toll and Congestion Capacity Units

ABSTRACT

Various implementations directed to price time priority queue routing for tolling capacity on roadways, shipping lanes and air traffic zones over curb, sidewalk, roadway, air space, outer space, waterborne space and parking capacity units are provided. Implementations of various methods and systems to transform navigation routes with two waypoints or a destination waypoint or a series sequence of waypoints into objects which have associated price-time priority queues or other prioritizations for transformed toll and congestion capacity units and toll and congestion capacity unit specifications. The present disclosed invention relates to combining the concepts of objected oriented programming, market price queues, navigation systems and social networking and toll and congestion capacity as a fungible asset class or toll and congestion capacity as an open market with trading and securitization transformations.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of: U.S. provisional patent application Ser. No. 62/927,081, filed Oct. 28, 2019 and titled “TOLL AND CONGESTION COMMUNTY OBJECTS WITH PRICE-TIME PRIORITY QUEUES FOR TRANSFORMED TOLL AND CONGESTION CAPACITY UNITS;” U.S. provisional patent application Ser. No. 62/927,025, filed Oct. 28, 2019 and titled “CURB COMMUNTY OBJECTS WITH PRICE-TIME PRIORITY QUEUES FOR TRANSFORMED CURB CAPACITY UNITS;” U.S. provisional patent application Ser. No. 63/027,344, filed May 19, 2020 and titled “TIME INTERVAL GEOLOCATION COMMUNITY OBJECTS WITH PRICE TIME PRIORITY QUEUES FOR TRANSFORMED TIME INTERVAL GEOLOCATION UNITS;” U.S. provisional patent application Ser. No. 63/039,918, filed Jun. 16, 2020 and titled “VIRTUAL REALITY, AUGMENTED REALITY, MIXED REALITY DATA EXCHANGE SOCIAL NETWORK WITH MULTI-DIMENSIONAL MAP TILE PORTING;” U.S. provisional patent application Ser. No. 63/044,997, filed Jun. 26, 2020 and titled “MULTI-DIMENSIONAL CLASSIFICATION OBJECT MATRICES TO ESTIMATE MULTI-DIMENSIONAL REPRESENTATIONS WITH MULTI-FUNCTION DEVICE;” U.S. provisional patent application Ser. No. 63/052,159, filed Jul. 15, 2020 and titled “MULTI-DIMENSION INFORMATION SERVICE HELMET METHOD AND SYSTEM;” and U.S. provisional patent application Ser. No. 63/051,373, filed Jul. 13, 2020 and titled “VIRTUAL POWER PLANT OPTIMIZATION METHOD AND SYSTEM;” each of which is herein incorporated by reference.

This application is a continuation-in-part of U.S. patent application Ser. No. 16/589,229, entitled “TRANSPORTATION AND FREIGHT CAPACITY UNITS,” filed Oct. 1, 2019; which is a continuation-in-part of U.S. patent application Ser. No. 16/556,838, entitled “FINANCIAL SWAP INDEX METHOD AND SYSTEM ON TRANSPORTATION CAPACITY UNITS AND TRADING DERIVATIVE PRODUCTS BASED THEREON,” filed Aug. 30, 2019; which is a continuation-in-part of U.S. patent application Ser. No. 16/274,490, entitled “ROUTE COMMUNITY OBJECTS WITH PRICE-TIME PRIORITY QUEUES FOR TRANSFORMED TRANSPORTATION UNITS,” filed Feb. 13, 2019; which is a continuation-in-part of U.S. patent application Ser. No. 16/258,658, entitled “NAVIGATION ROUTES AS COMMUNITY OBJECT VIRTUAL HUB SEQUENCES TO WHICH USERS MAY SUBSCRIBE,” filed Jan. 27, 2019; which is a continuation-in-part of U.S. patent application Ser. No. 16/257,032, entitled “SECURITIZATION OF TRANSPORTATION UNITS,” filed Jan. 24, 2019; which is a continuation-in-part of U.S. patent application Ser. No. 16/242,981, entitled “STRATEGY GAME LAYER OVER PRICE BASED NAVIGATION,” filed Jan. 8, 2019; which is a continuation-in-part of U.S. patent application Ser. No. 16/242,967, entitled “PRICE BASED NAVIGATION,” filed Jan. 8, 2019; which is a continuation-in-part of U.S. patent application Ser. No. 16/239,485, entitled “MARKET LAYER PRICE QUEUE ROUTING FOR MULTI-LAYERED NODAL NETWORK TOPOLOGY FOR A MULTI-MODAL SECURE FORWARD MARKET AUCTION IN TRANSPORTATION CAPACITY AND SPACE,” filed Jan. 3, 2019; which is a continuation-in-part of U.S. patent application Ser. No. 16/183,647, entitled “FINANCIAL SWAP PAYMENT STRUCTURE METHOD AND SYSTEM ON TRANSPORTATION CAPACITY UNIT ASSETS,” filed Nov. 7, 2018; which is a continuation-in-part of U.S. patent application Ser. No. 16/167,525, entitled “MULTI-LAYERED NODAL NETWORK TOPOLOGY FOR A MULTI-MODAL SECURE FORWARD MARKET AUCTION IN TRANSPORTATION CAPACITY AND SPACE,” filed Oct. 22, 2018; which is a continuation-in-part of U.S. patent application Ser. No. 15/877,393, entitled “ELECTRONIC FORWARD MARKET EXCHANGE FOR TRANSPORTATION SEATS AND CAPACITY IN TRANSPORTATION SPACES AND VEHICLES,” filed Jan. 23, 2018; which is a continuation-in-part of U.S. patent application Ser. No. 15/266,326, entitled “IMPLEMENTATIONS OF A COMPUTERIZED BUSINESS TRANSACTION EXCHANGE FOR VARIOUS USERS,” filed Sep. 15, 2016; each of which is herein incorporated by reference.

This application is also a continuation-in-part of U.S. patent application Ser. No. 16/397,685, entitled “TUTORING COMMUNITY OBJECTS WITH PRICE TIME PRIORITY QUEUES FOR TRANSFORMED TUTORING UNITS,” filed Apr. 29, 2019; which is a continuation-in-part of U.S. patent application Ser. No. 16/359,841, entitled “PARKING COMMUNITY OBJECTS WITH PRICE-TIME PRIORITY QUEUES FOR TRANSFORMED PARKING UNITS,” filed Mar. 20, 2019; which is a continuation-in-part of U.S. patent application Ser. No. 16/357,241, entitled “RENEWABLE ENERGY COMMUNITY OBJECTS WITH PRICE TIME PRIORITY QUEUES FOR TRANSFORMED RENEWABLE ENERGY UNITS,” filed Mar. 18, 2019; which is a continuation-in-part of U.S. patent application Ser. No. 16/183,647, entitled “FINANCIAL SWAP PAYMENT STRUCTURE METHOD AND SYSTEM ON TRANSPORTATION CAPACITY UNIT ASSETS,” filed Nov. 7, 2018; which is a continuation-in-part of U.S. patent application Ser. No. 16/167,525, entitled “MULTI-LAYERED NODAL NETWORK TOPOLOGY FOR A MULTI-MODAL SECURE FORWARD MARKET AUCTION IN TRANSPORTATION CAPACITY AND SPACE,” filed Oct. 22, 2018; which is a continuation-in-part of U.S. patent application Ser. No. 15/877,393, entitled “ELECTRONIC FORWARD MARKET EXCHANGE FOR TRANSPORTATION SEATS AND CAPACITY IN TRANSPORTATION SPACES AND VEHICLES,” filed Jan. 23, 2018; which is a continuation-in-part of U.S. patent application Ser. No. 15/266,326, entitled “IMPLEMENTATIONS OF A COMPUTERIZED BUSINESS TRANSACTION EXCHANGE FOR VARIOUS USERS,” filed Sep. 15, 2016; each of which is herein incorporated by reference.

BACKGROUND OF THE INVENTION

The following descriptions and examples are not admitted as prior art by virtue of their inclusion within this section.

In some scenarios, road congestion and tolling capacity on roadways, shipping lanes and air traffic zones may not utilize dynamic virtual topology market queues or price time priority queues. Such queues may not be used because tolling, sea control or air traffic control systems may typically be considered to be closed, non-transparent, non-substitutable, and/or non-transferable, no cost of cover calculations exist, and the construct for dynamic routing based on tolling, sea control tolls or air traffic control toll capacity unit marketplaces across delivery, transit, parking, air congestion capacity or generalized space capacity may not be understood. Further, in such scenarios, legal or physical transformations may not exist for tolling over roadway, sea or air traffic zones or transportation or freight capacity units to trade as commodities, which may prevent the formation of tolling over roadway, seaway or airways for transportation, delivery, parking or capacity systems routing sequences that are based upon market dynamic, transparent market price-based inputs in edge weights or edge values. In these scenarios, methods and systems may lack the legal and physical calculation mechanics for tolling over roadway, seaway, air traffic control lanes, outer space lanes or curb side parking for delivery, curb space units, sidewalk space units, parking spot space units, air space units, outer space capacity units, which may limit vehicle capacity routing or transportation, delivery, parking or capacity systems utilization, analysis and equation usefulness.

Deficiencies in market structure and legal and physical tolling over roadway, seaway or airways for routing, travel, parking for delivery, curb space units, sidewalk space units, parking spot space units, air space units, outer space capacity units may not allow for the transferability of an underlying air, sea, or land capacity space, parking spot, transit curb space, delivery curb space capacity units, which may inhibit flexibility to exchange such an asset and may lead to the development of monopolistic systems. Further, in some scenarios, tolling over roadway, seaway or airways for general space capacity, curb capacity, parking capacity or air space capacity options may allow for transferability, but they may lack structures which account for force majeure contingencies, remedies for curb capacity, parking capacity or air space capacity unit delivery failures, events of default, remedies, calculation formulas for termination payments, or independent valuation transformations. In such scenarios, the ability to trade the value of tolling over roadway, seaway or airways for physical curb side parking for delivery, curb space units, sidewalk space units, parking spot space units, air space units, road space units or outer space capacity units may be limited.

SUMMARY

Described herein are implementations of various technologies relating to a price time priority queue routing for tolling over roadway, seaway or airways for general space, curb, parking, sidewalk space capacity units. The claimed subject matter is not limited to implementations that solve any or all of the noted disadvantages. Further, the summary section is provided to introduce a selection of concepts in a simplified form that are further described below in the detailed description section. The summary section is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used to limit the scope of the claimed subject matter.

Described herein are implementations of various technologies relating to a price time priority queue routing for tolling over roadway, seaway or airways for general space, roadway, air lane, sea lane, curb, parking, sidewalk space capacity units. The aforementioned deficiencies and other problems associated with the general roadway congestion, navigation systems, air traffic control systems, sea traffic control systems, passenger toll and congestion capacity for both transit and freight markets, securitization of toll and congestion capacity units, other novel systems and interfaces and how toll and congestion capacity functions with large inefficiencies which use electronic devices to deliver freight, food or transportation network companies or transit services are reduced or eliminated by the disclosed method and system. Further described herein are implementations of various technologies relating to a price time priority queue routing for tolling over roadway, seaway or airways for general space, roadway, air lane, sea lane, curb, parking, sidewalk space capacity units. In one implementation, a method may include receiving origin location data and destination location data from a first user, where the origin location data corresponds to a geographic origin and the destination location data corresponds to a geographic destination, where the origin location data and destination location data may be the same location or different locations. The method may also include latitude, longitude and altitude data for the geolocation hub location. The method may also include generating a plurality of routes based on the origin location data and the destination location data for tolling over roadway, seaway or airways for general space, roadway, air lane, sea lane, curb, parking, sidewalk space capacity units. The method may further include determining a plurality of virtual hubs along the plurality of routes, where the plurality of virtual hubs includes a first virtual hub based on the origin location data and a second virtual hub based on the destination location data. The method may additionally include receiving tolling over roadway, seaway or airways for general space, roadway, air lane, sea lane, curb, parking, sidewalk space capacity unit cost data for the plurality of routes for one or more geolocation exchange units, where the one or more geolocation exchange units corresponds to a predetermined space, tolling over roadway, seaway or airways for general space, roadway, air lane, sea lane, curb, parking, sidewalk space capacity units between two or more virtual hubs with geolocation data of latitude, longitude and altitude, and where the tolling over roadway, seaway or airways for general space, roadway, air lane, sea lane, curb, parking, sidewalk space capacity unit capacity cost data includes data relating to arrival and departure times, curb capacity, roadway capacity, air space capacity, shipping capacity, air traffic control capacity, drone or unmanned aircraft capacity or parking capacity or air space capacity expenses, or combinations thereof. In addition, the method may include receiving market depth data for a geolocation exchange for the one or more geolocation exchange units based on the plurality of curb capacity or parking capacity or air space capacity routes, where the market depth data includes one or more bid prices and one or more offer prices for the one or more geolocation exchange units. The method may also include selecting an optimized route of the plurality of routes for the one or more geolocation exchange units based on an objective function, where the objective function uses the curb capacity or road capacity or parking capacity or air space capacity or shipping lane capacity cost data, the market depth data, or combinations thereof.

In another implementation, a computing system may include one or more processors, and the computing system may also include one or more memory having program instructions executable by the one or more processors to receive origin location data and destination location data from a first user, where the origin location data corresponds to a geographic origin and the destination location data corresponds to a geographic destination. The one or more memory may also have program instructions executable by the one or more processors to generate a plurality of routes based on the origin location data and the destination location data. The one or more memory may further have program instructions executable by the one or more processors to determine a plurality of virtual hubs along the plurality of routes, where the plurality of virtual hubs includes a first virtual hub based on the origin location data and a second virtual hub based on the destination location data. The one or more memory may additionally have program instructions executable by the one or more processors to receive travel cost data for the plurality of tolling over roadway, seaway or airways for general space, roadway, air lane, sea lane, curb, parking, sidewalk space capacity unit routes for one or more geolocation exchange units, where the one or more geolocation exchange units corresponds to a predetermined tolling over roadway, seaway or airways for general space, roadway, air lane, sea lane, curb, parking, sidewalk space capacity unit space traveling from the first virtual hub to the second virtual hub, the first virtual hub and second virtual hub may be the same location or two locations which span a plurality of longitude, latitude and altitude coordinates, and where the travel cost data includes data relating to travel time, travel expenses, parking costs, curb parking costs, space capacity costs, congestion costs, air traffic control costs, shipping lane costs or combinations thereof. In addition, the one or more memory may have program instructions executable by the one or more processors to receive market depth data for a geolocation exchange for the one or more geolocation exchange units based on the plurality of curb capacity or tolling over roadway, seaway or airways for general space, roadway, air lane, sea lane, curb, parking, sidewalk space capacity unit capacity routes, where the market depth data includes one or more bid prices and one or more offer prices for the one or more geolocation exchange units. The one or more memory may also have program instructions executable by the one or more processors to select an optimized tolling over roadway, seaway or airways for general space, roadway, air lane, sea lane, curb, parking, sidewalk space capacity unit capacity route of the plurality of tolling over roadway, seaway or airways for general space, roadway, air lane, sea lane, curb, parking, sidewalk space capacity unit capacity routes for the one or more geolocation exchange units based on an objective function, where the objective function uses the travel cost data, the market depth data, parking or curb capacity costs, air traffic control capacity costs, sea lane capacity costs, outer space capacity costs or combinations thereof.

In yet another implementation, a non-transitory computer-readable medium may have stored thereon a plurality of computer-executable instructions which, when executed by a computer, cause the computer to receive origin location data and destination location data from a first user, where the origin location data corresponds to a geographic origin and the destination location data corresponds to a geographic destination. The plurality of computer-executable instructions which, when executed by a computer, may also cause the computer to generate a plurality of tolling over roadway, seaway or airways for general space, roadway, air lane, sea lane, curb, parking, sidewalk space capacity unit routes based on the origin location data and the destination location data. The plurality of computer-executable instructions which, when executed by a computer, may further cause the computer to determine a plurality of virtual hubs along the plurality of routes, where the plurality of virtual hubs includes a first virtual hub based on the origin location data and a second virtual hub based on the destination location data. The plurality of computer-executable instructions which, when executed by a computer, may additionally cause the computer to receive travel cost data for the plurality of tolling over roadway, seaway or airways for general space, roadway, air lane, sea lane, curb, parking, sidewalk space capacity unit capacity routes for one or more geolocation exchange units, where the one or more geolocation exchange units corresponds to a predetermined space traveling from the first virtual hub to the second virtual hub, wherein the first virtual hub and the second virtual hub may be the same location or different latitude, longitude and altitude coordinates, and where the travel cost data includes data relating to travel time, travel expenses, curb capacity or sea lane capacity, air traffic control capacity, parking capacity or air space capacity or combinations thereof. In addition, the plurality of computer-executable instructions which, when executed by a computer, may cause the computer to receive market depth data for a geolocation exchange for the one or more geolocation exchange units based on the plurality of c tolling over roadway, seaway or airways for general space, roadway, air lane, sea lane, curb, parking, sidewalk space capacity unit routes, where the market depth data includes one or more bid prices and one or more offer prices for the one or more geolocation exchange units. The plurality of computer-executable instructions which, when executed by a computer, may also cause the computer to select an optimized tolling over roadway, seaway or airways for general space, roadway, air lane, sea lane, curb, parking, sidewalk space capacity unit route of the plurality of tolling over roadway, seaway or airways for general space, roadway, air lane, sea lane, curb, parking, sidewalk space capacity unit routes for the one or more geolocation exchange units based on an objective function, wherein the objective function uses the travel cost data, the market depth data, curb capacity or parking capacity or sea lane capacity, roadway congestion capacity, air space capacity or combinations thereof.

The above referenced summary section is provided to introduce a selection of concepts in a simplified form that are further described below in the detailed description section. The summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used to limit the scope of the claimed subject matter. Furthermore, the claimed subject matter is not limited to implementations that solve any or all disadvantages noted in any part of this disclosure.

BRIEF DESCRIPTION OF THE DRAWINGS

Implementations of various technologies will hereafter be described with reference to the accompanying drawings. It should be understood, however, that the accompanying drawings illustrate only the various implementations described herein and are not meant to limit the scope of various technologies described herein.

FIG. 1 illustrates a schematic diagram of a plurality of virtual toll and congestion hub sequences data transformations into waypoint combinations as community objects to which users may subscribe and associate price-time priority queues or other priority schema in accordance with implementations of various techniques described herein.

FIG. 2 illustrates a schematic diagram of an exemplary network configuration and of a virtual toll and congestion hub sequences data transformation into a waypoint combination as community object to which users may subscribe and associate price-time priority queues or other priority schema in accordance with implementations of various techniques described herein.

FIG. 3 illustrates an exemplary price-time priority queue for community route objects or waypoint combinations and community route object sequences for transformed toll and congestion capacity and freight toll and congestion units in accordance with implementations of various techniques described herein.

FIG. 4 illustrates an exemplary user interface with various international configurations of trading automobile or freight toll and congestion capacity in accordance with some embodiments in accordance with implementations of various techniques described herein.

FIG. 5 illustrates an exemplary user interface to select a specification grade of toll and congestion capacity or toll and congestion freight capacity with various timing specifications in accordance with some embodiments and implementations.

FIG. 6 illustrates an exemplary user interface with various term specifications for toll and congestion capacity or toll and congestion freight capacity in accordance with some embodiments and implementations.

FIG. 7 illustrates an exemplary user interface with various order types and order time in force designations for toll and congestion capacity or toll and congestion freight capacity in accordance with some embodiments and implementations.

FIG. 8 illustrates an exemplary user interface with various modes of toll and congestion capacity or toll and congestion freight capacity in accordance with some embodiments and implementations.

FIG. 9 illustrates an exemplary user interface with the distance between the user and a virtual hub pick up point for toll and congestion capacity or toll and congestion freight capacity as well as the distance between a user and a virtual drop off point for toll and congestion capacity or toll and congestion freight capacity in accordance with some embodiments and implementations.

FIG. 10 illustrates an exemplary user interface for settings and constraints of the toll and congestion capacity or toll and congestion freight capacity trading method and system in accordance with some embodiments and implementations.

FIG. 11 illustrates an exemplary user interface for transacting and trading domestic air travel toll and congestion capacity or air freight toll and congestion capacity in accordance with some embodiments and implementations.

FIG. 12 illustrates an exemplary user interface for transacting and trading international train toll and congestion capacity or train toll and congestion freight capacity in accordance with some embodiments and implementations.

FIG. 13 illustrates an exemplary user interface for transacting and trading international train toll and congestion capacity or train freight capacity in accordance with some embodiments and implementations.

FIG. 14 illustrates an exemplary user interface for transacting and trading various menu options within the system and method in accordance with some embodiments and implementations.

FIG. 15 illustrates a schematic diagram of a network configuration and implementations of methods which support the method and system of trading toll and congestion capacity in accordance with some embodiments and implementations.

FIG. 16 is a flow diagram illustrating methods exemplary users move through while participating, transacting and trading toll and congestion capacity or toll and congestion freight capacity in accordance with some embodiments and implementations.

FIG. 17 illustrates an exemplary user interface for displaying most frequent routes in accordance with some embodiments and implementations.

FIG. 18 illustrates an exemplary network topology of a virtual hub combination or series of multiple virtual hub combinations for use in the market auction platform for forward toll and congestion capacity or freight toll and congestion capacity method in accordance with some embodiments and implementations.

FIG. 19 illustrates an exemplary user interface to display the map of the virtual hub to virtual hub route of a given transaction for forward toll and congestion capacity or freight toll and congestion capacity units in accordance with some embodiments and implementations.

FIG. 20 illustrates an exemplary user interface to display the results of a security check and verification of users identity for forward toll and congestion capacity or freight toll and congestion capacity units in accordance with some embodiments and implementations.

FIG. 21 illustrates an exemplary user interface to display the status of the virtual hub to virtual hub route of a given transaction for forward toll and congestion capacity or freight toll and congestion capacity units in accordance with some embodiments and implementations.

FIG. 22 illustrates an exemplary user interface to display the status of the virtual hub to virtual hub route of a given transaction for forward toll and congestion capacity or freight toll and congestion capacity units in accordance with some embodiments and implementations.

FIG. 23 illustrates an exemplary user interface to display the status of the virtual hub to virtual hub route of a given transaction for forward toll and congestion capacity or freight toll and congestion capacity units in accordance with some embodiments and implementations.

FIG. 24 illustrates an exemplary user interface to display a multi-hub, virtual-hub sequence given a start and end point for a transaction auction for forward toll and congestion capacity or freight capacity units in accordance with some embodiments and implementations.

FIG. 25 illustrates an exemplary user interface to display open or restriction settings for auctions of the toll and congestion capacity or freight toll and congestion forward market system and method in accordance with some embodiments and implementations.

FIG. 26 illustrates an exemplary user interface to display inbound and outbound package, cargo or freight QR scans or UPC scans or pictures to document freight toll and congestion units in which are delivered against the forward toll and congestion market auction for two or more virtual toll and congestion hubs in accordance with some embodiments and implementations.

FIG. 27 illustrates an exemplary user interface to display a forward freight auction for a toll and congestion capacity unit a given hub or multi-hub combination in accordance with some embodiments and implementations.

FIG. 28 illustrates an exemplary user interface and database configuration which allow user identity or criminal record or transaction history to be verified in accordance with some embodiments and implementations.

FIG. 29 illustrates an exemplary user interface and database configuration for account balances and payment for the forward market auctions of toll and congestion capacity and freight capacity between virtual hubs in accordance with some embodiments and implementations.

FIG. 30 illustrates an exemplary method and system configuration of multiple virtual toll and congestion hub topology auctions in accordance with some embodiments and implementations.

FIG. 31 illustrates an exemplary method and system configuration of the integration interface with GPS map routing such as TomTom or Apple Maps or other third party map routing software in accordance with some embodiments and implementations.

FIG. 32 illustrates an exemplary method and system configuration of the integration interface with GPS map routing such as Google Maps or other third party map routing software applications in accordance with some embodiments and implementations.

FIG. 33 illustrates an exemplary method and system configuration of the integration interface with GPS map routing such as Waze Maps or other third party map routing software applications in accordance with some embodiments and implementations.

FIG. 34 illustrates an exemplary method and system configuration of the integration interface with GPS map routing such as Open Street Maps or other third party map routing software applications in accordance with some embodiments and implementations.

FIG. 35 illustrates an exemplary method and system configuration of the integration interface with GPS map routing in a vehicle such as Tesla, VW, Audi, Daimler, GM, Ford, Honda, Fiat, Nissan, Hyundai, Renault, Suzuki, BMW, Mazda, Dongfeng, Great Wall, Geely, BAIC, Tata, Toyota or any other third party map routing software applications inside a vehicle in accordance with some embodiments and implementations.

FIG. 36 illustrates an exemplary user interface and database configuration which allow the user to play a strategy based game overlay on the priced based navigation toll and congestion in accordance with some embodiments and implementations.

FIG. 37 illustrates an exemplary user interface and database configuration which allow the user to play a strategy based game overlay on the priced based navigation toll and congestion with augmented reality in accordance with some embodiments and implementations.

FIG. 38 illustrates an exemplary user interface and database configuration which allow the user to play a strategy based game overlay on the priced based navigation toll and congestion with augmented reality in accordance with some embodiments and implementations.

FIG. 39 illustrates an exemplary user interface and database configuration which allow the user to play a strategy based game overlay on the priced based navigation toll and congestion with augmented reality in accordance with some embodiments and implementations.

FIG. 40 illustrates an exemplary user interface and database configuration which allow the user to select model, make, type, year, fuel type in configuration for price based navigation in accordance with some embodiments and implementations.

FIG. 41 illustrates an exemplary user interface and database configuration which displays a plurality of metrics for the performance of the user in the game overlay and general system and method of priced based navigation in accordance with some embodiments and implementations.

FIG. 42 illustrates an exemplary user interface and database configuration which displays a plurality of routes between two user requested toll and congestion hubs indexed based on the pricing of toll and congestion capacity units or toll and congestion capacity unit securities and the associated open market transaction interface for those transformed toll and congestion capacity unit securities in accordance with some embodiments and implementations.

FIG. 43 illustrates an exemplary flow chart of steps in the toll and congestion capacity unit security data transformation and presentation of the toll and congestion capacity unit security with integration to navigation systems which is another data transformation in accordance with some embodiments and implementations.

FIG. 44 illustrates an exemplary user interface of virtual toll and congestion hub sequences as community object(s) to which users may subscribe in accordance with some embodiments and implementations.

FIG. 45 illustrates an exemplary user interface of an exemplary virtual toll and congestion hub sequence as a community object and the associated attributes in accordance with some embodiments and implementations.

FIG. 46 illustrates an exemplary multi-virtual hub sequence community object combination in accordance with some embodiments and implementations.

FIG. 47 illustrates an exemplary menu user interface for the method and system of virtual hub sequence communities combined with the toll and congestion capacity unit market system and method in accordance with some embodiments and implementations.

FIG. 48 illustrates and exemplary transformation preamble formula to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 49 illustrates and exemplary transformation preamble formula to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 50 illustrates and exemplary transformation definition formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 51 illustrates and exemplary transformation definition formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 52 illustrates and exemplary transformation definition formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 53 illustrates and exemplary transformation definition formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 54 illustrates and exemplary transformation definition formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 55 illustrates and exemplary transformation definition formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 56 illustrates and exemplary transformation definition and transaction terms and condition formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 57 illustrates and exemplary transformation definition and transaction terms and condition formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 58 illustrates and exemplary transformation definition and transaction terms and condition formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 59 illustrates and exemplary transformation force majeure and remedies for product delivery failure formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 60 illustrates and exemplary transformation event of default remedy formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 61 illustrates and exemplary transformation event of default remedy formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 62 illustrates and exemplary transformation event of default remedy formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 63 illustrates and exemplary transformation event of default remedy formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 64 illustrates and exemplary transformation event of default remedy formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 65 illustrates and exemplary transformation event of default remedy and payment formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 66 illustrates and exemplary transformation payment and limitation of remedy and liability and damages formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 67 illustrates and exemplary transformation limitation of remedy and liability and damages formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 68 illustrates and exemplary transformation limitation of remedy and liability and damages and financial information and tax formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 69 illustrates and exemplary transformation credit supporting formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 70 illustrates and exemplary transformation Transportation Capacity Unit formulas to create a “Transportation Capacity Unit” transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 71 illustrates and exemplary transformation Transportation Capacity Unit formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 72 illustrates and exemplary transformation Transportation Capacity Unit formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 73 illustrates and exemplary transformation Transportation Capacity Unit formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 74 illustrates and exemplary transformation Transportation Capacity Unit formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 75 illustrates and exemplary transformation Transportation Capacity Unit formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 76 illustrates and exemplary transformation Transportation Capacity Unit formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 77 illustrates and exemplary transformation Transportation Capacity Unit formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 78 illustrates and exemplary transformation Transportation Capacity Unit formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 79 illustrates and exemplary transformation Transportation Capacity Unit formulas to create a “Transportation Capacity Unit” for transportation toll and congestion or freight toll and congestion capacity units in accordance with some embodiments.

FIG. 80 illustrates and exemplary transformation Transportation Capacity Unit for transportation toll and congestion or freight toll and congestion capacity units notice correspondence in accordance with some embodiments.

FIG. 81 illustrates and exemplary transformation of a Transportation Capacity Unit flow chart of a plurality of formula transformations in accordance with some embodiments.

FIG. 82 illustrates and exemplary transformation of a Transportation Capacity Unit flow chart of a plurality of formula transformations in accordance with some embodiments.

FIG. 83 illustrates and exemplary transformation of a Transportation Capacity Unit flow chart of a plurality of formula transformations in accordance with some embodiments.

FIG. 84 illustrates and exemplary transformation of a Transportation Capacity Unit flow chart of a plurality of formula transformations in accordance with some embodiments.

FIG. 85 illustrates a schematic diagram of a computing system in which the various technologies described herein may be incorporated and practiced in accordance with some embodiments.

DETAILED DESCRIPTION

The discussion below is directed to certain specific implementations. It is to be understood that the discussion below is only for the purpose of enabling a person with ordinary skill in the art to make and use any subject matter defined now or later by the patent “claims” found in any issued patent herein. In other instances, well-known methods, procedures, components, circuits and networks have not been described in detail so as not to unnecessarily obscure aspects of the embodiments.

It will also be understood that, although certain elements of the invention and subject matter will be described in a certain order, the order is not intended to be limiting to the invention as many steps may be performed in a plurality of configurations to accomplish the invention of using various technologies to participate, trade and transact toll and congestion capacity and freight toll and congestion units as a physical forward commodity. It will be further understood that the terms “comprises” or “comprising,” when used in this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof.

The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used in the description of the invention, the singular forms “a”, “an” and “the” are intended to also include the plural forms as well, unless the context clearly indicates otherwise. It will also be understood that the term “and/or” as used herein refers to and encompasses any and all possible combinations of one or more of the associated listed items. It will be further understood that the terms “comprises” and/or “comprising,” when used in this specification, specify the presence of stated features, integers, steps, operations, elements, components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof.

As used herein, the term “if” may be construed to mean “when” or “upon” or “in response to determining” or “in response to detecting,” depending on the context. Similarly the phrase “if it is determined” or “if [a stated condition or event] is detected” may be construed to mean “upon determining” or “in response to determining” or “upon detecting [the stated condition or event]” or “in response to detecting [the stated condition or event],” depending on the context. Similarly, the meaning of “toll and congestion capacity” may be used interchangeably with “sidewalk capacity” or “transportation capacity” to represent space on the road near a toll and congestion or the sidewalk adjacent to the toll and congestion or sidewalk space near a toll and congestion. Similarly, the meaning of “security” may be used interchangeably with “unitized object” or “unitization” or “forward toll and congestion capacity object” to represent space on the road near a toll and congestion or the sidewalk adjacent to the toll and congestion or sidewalk space near a toll and congestion that is tradable in markets from legal transformations.

A computing device, as described herein, may include any computing implementation known to those skilled in the art, including mobile computing devices. In some embodiments, a mobile computing device may be substituted for a fixed stationary computing device or a virtual reality headset or a mixed reality headset or an augmented reality headset or an audio interfaced computer device. In some embodiments, there may also occur on a projection computing device or in any other method or system which communicates and integrates the use of a network, community route processor, my route processor, sequence route processor, global positioning system network, mobile computing devices, servers, forward commodity forward market auction database, price-time priority queues, grouping software instructions for hubs, securitization transformations and specifications, game servers, indexing algorithms for toll and congestion capacity unit securities on various navigation routes, navigation servers, virtual hub topology methods and systems, transparent open access user interface pricing systems, blockchain audit and safety methods, facial recognition, fingerprint recognition or photo recognition of users for security and identity check, algorithms for no arbitrage conditions and constraints with a user interface or graphical user interface formatted on mobile or stationary computing devices over various mediums which are connected through a network for the purpose of grouping users into virtual toll and congestion hub sequences of community objects as a gateway to participating, transacting or trading toll and congestion capacity or freight toll and congestion capacity units between combinations of virtual toll and congestion hubs as a forward commodity in an auction or priority schema.

Various implementations directed to price time priority queue routing for curb, parking or general space capacity units for delivery, parking, standing, waiting, docking, hovering, across transit and freight and travel will now be described in the following paragraphs with reference to FIGS. 1-85.

The following paragraphs provide various techniques of various embodiments described herein such as illustrated as in FIG. 1. In one implementation as illustrated in FIG. 1, a user 110 may be assigned or may join a virtual route community 101, 103 which is a sequence of virtual hub(s). In some implementations and embodiments, the virtual toll and congestion hub sequence may be assigned a metadata tag such as #ConstitutionAve 102 which is short for a longer full name sequence such as Constitution Avenue, Washington, D.C. In some embodiments, the origin virtual hub 105, may be a specific toll and congestion address and geolocation data in the city of Washington, D.C. along Constitution Avenue. In some implementations and embodiments, the route 119 between the toll and congestion address of an address on Constitution Ave such as the street address of two Constitution Avenue virtual toll and congestion hub 105 and the fifty Constitution Avenue virtual toll and congestion hub 113 may be a sequence of two virtual toll and congestion hubs. In some implementations and embodiments, there may be many one or more trucks 118 along the toll and congestion route 119 or cars 117 or additional trucks 116 or additional cars 114 which are headed in a certain direction along the route toll and congestion 119. In some embodiments, additional vehicles 106, 107, 108, 109, 104 or bikes, eBikes or eScooters 111 may be headed the other direction along the virtual toll and congestion hub sequence 119 between two virtual toll and congestion hub points 105, 113. In some embodiments, additional user(s) 112 may join the virtual hub route toll and congestion sequence community 103. In yet another exemplary implementation, a user 110 may be assigned or may join a virtual route toll and congestion community 122, 120, 122, 156 which are a sequence of virtual toll and congestion hub(s) or virtual toll and congestion hub(s) zone(s). In some implementations and embodiments, the virtual hub toll and congestion sequence may be assigned a metadata tag such as #ConstitutionAve 102 which is may represent an exemplary street toll and congestion which has a plurality of passenger loading zones 122, no parking zones 121 and freight or food loading zones 120 or sidewalk zones 156. In some embodiments, the street may have a plurality of vehicles such as cars 123, 124, 126, 127, 131, 130 and trucks 128, 132, 129 and eScooters 154, eBikes 155, bikes 153 as well as airplanes for air landing strips, autonomous vehicles 130, bikes, boats for shipping lanes or ports, busses, drone landing areas or unmanned aerial craft landing areas on the toll and congestion, or a limo or livery service, or motorcycle, or moped, or shuttle for space landing areas, or spaceship for space landing areas, or subway for subway stations, or taxis or transportation network companies or trains, or package delivery services on a plurality of modes or robotic delivery services. In some implementations and embodiments, there may be many one or more trucks 128 along the virtual toll and congestion route 119 or cars 125 which are headed in a certain direction along the virtual toll and congestion route or virtual toll and congestion space 119. In some embodiments, the graphical user interface may communicate with the network 160 and receive instructions from the toll and congestion unit queue processor 162 and server 163 and memory 164 as well as the toll and congestion capacity forward market database base server 161. In yet another exemplary implementation, a user 112 or additional user 110 may be assigned or may join a virtual toll and congestion community 119 which is a sequence of virtual toll and congestion hub(s) from the geofence or crossing the geofence.

In some implementations and embodiments, virtual toll and congestion hub sequences such as the street address of two Constitution Avenue virtual toll and congestion hub 105 and the fifty Constitution Avenue virtual toll and congestion hub 113 may be a sequence of two virtual toll and congestion hubs are transformed into community objects which may then be assigned a plurality of attributes in the same sense as a class in the Java programming language has methods as a part of the class object in object oriented programming. In some implementations and embodiments, the data transformation of a virtual toll and congestion hub sequence into a community object allows the similar benefits of the data transformations involved in computing languages with methods which help the instructions of the computer program communicate in an organized manner using modular logic. In some implementations and embodiments, virtual toll and congestion hub sequences such as 105 to 113 #ConstitutionAve 102 may be combined with other virtual hub sequences to extend the series sequence. As we have discussed at length in the previous sections of the disclosed invention, while there may be hundreds or thousands or millions of people along various toll and congestion capacity virtual hub sequences, there currently exists no method or system of organizing a route toll and congestion or sidewalk or virtual toll and congestion hub sequence into a transformed data community object. The attributes of communities allow for superior communication, accountability and even transactions to occur within a community object 101. In some embodiments, the data transformation of a virtual hub sequence community object 101 allows a plurality of network members 110, 112 to be assigned virtual toll and congestion route communities 103 based on a plurality of attributes, prior GPS location histories, geofencing, navigation search queries or other attributes. In some implementations and embodiments, virtual toll and congestion hub sequences which have been transformed into community objects 101 provide greater communication and organizational ability for a market to transact toll and congestion capacity unit(s) and provide a gateway for those toll and congestion capacity unit transactions as described in U.S. patent application Publication, Ser. No. 15/877,393, “Electronic Forward market exchange for transportation capacity seats and capacity in toll and congestion capacity spaces and vehicles,” filed Jan. 23, 2018, the entirety of which is incorporated by reference herein.

In some implementations and embodiments, virtual toll and congestion hub sequences which have been transformed into community objects 101 communicate through a network 160 to associate a price-time priority queue 133, 134, 135, 136, 137, 138, 139, 140, 141, 142, 143, 144, 145, 146, 147, 148, 149, 150, 151 for a transformed toll and congestion capacity community object using a toll and congestion capacity unit queue processor 162, a server 163, memory 164 and a toll and congestion capacity forward market database server 161. In some other embodiments, the price-time priority queue 133, 134, 135, 136, 137, 138, 139, 140, 141, 142, 143, 144, 145, 146, 147, 148, 149, 150, 151 may also be organized into other priority schema queue structures and sequences. In some embodiments, the virtual hub sequences or community objects 101 may be independent or sequenced to construct a waypoint sequence of multiple linked virtual toll and congestion hub route community objects 101. In some embodiments, the associated price-time priority queue 133, 134, 135, 136, 137, 138, 139, 140, 141, 142, 143, 144, 145, 146, 147, 148, 149, 150, 151 for toll and congestion capacity units may have generated processing and user interface display instructions from the toll and congestion capacity unit queue processor 162, the server 163, the memory 164 and a toll and congestion capacity forward market database server 161 through a network 160. In some embodiments, the price-time priority queue 133, 134, 135, 136, 137, 138, 139, 140, 141, 142, 143, 144, 145, 146, 147, 148, 149, 150, 151 for transformed toll and congestion capacity units may process and display a plurality of time and date sequences for a plurality of forward delivery periods for transformed toll and congestion capacity unit(s). In some embodiments, an exemplary priority schema may follow the buy quantity of toll and congestion capacity units 133 label which a price-time priority schema to label the buy quantity at a given price and time of toll and congestion capacity units as the first price time priority position buy quantity of two toll and congestion capacity units 134. In some implementations and embodiments, the second price-time priority queue position may be represented by a buy quantity of one 135 for toll and congestion capacity units at a given virtual toll and congestion hub sequence. In some implementations and embodiments, the third price-time priority queue position may be represented by a buy quantity of one 136 for toll and congestion capacity units at a given virtual toll and congestion hub sequence. In some implementations and embodiments, an exemplary priority schema buy prices may follow the price of toll and congestion capacity units 145 label which a price-time priority schema to label the price at a given price and time of toll and congestion capacity units as the first price time priority position price of $0.84 toll and congestion capacity units 143. In some implementations and embodiments, the second price-time priority queue position may be represented by a buy price of $0.83 144 for toll and congestion capacity units at a given virtual toll and congestion hub sequence. In some embodiments, the third price-time priority queue position may be represented by a price of $0.82 142 for toll and congestion capacity units at a given virtual toll and congestion hub sequence. In some implementations and embodiments, exemplary priority schema sell prices may follow the price of toll and congestion capacity units 146 label which a price-time priority schema to label the price at a given sell price and time of toll and congestion capacity units as the first price time priority position price of $0.85 toll and congestion capacity units 148. In some implementations and embodiments, the second price-time priority queue position may be represented by a sell price of $0.86 147 for toll and congestion capacity units at a given virtual toll and congestion hub sequence. In some implementations and embodiments, the third price-time priority queue position may be represented by a sell price of $0.87 141 for toll and congestion capacity units at a given virtual toll and congestion hub sequence. In some embodiments, an exemplary priority schema may follow the sell quantity of toll and congestion capacity units 149 label which a price-time priority schema to label the quantity at a given price and time of toll and congestion capacity units as the first price time priority position sell quantity of three toll and congestion capacity units 150. In some embodiments, the second price-time priority queue position may be represented by a sell quantity of one 151 for toll and congestion capacity units at a given virtual toll and congestion hub sequence. In some embodiments, the third price-time priority queue position may be represented by a sell quantity of one 140 for toll and congestion capacity units at a given virtual toll and congestion hub sequence. In some implementations and embodiments, the date 137 may be selected for a given toll and congestion capacity unit specification. In some embodiments, the time 138 may be selected for a given toll and congestion capacity unit specification. In some implementations and embodiments, the product 139 may be selected for a given toll and congestion capacity unit specification.

In some implementations and embodiments, eScooters 154 or eBikes 155 or bikes 153 may be on a sidewalk 156 or toll and congestion zones 122, 121, 120 wherein a price-time priority queue 133, 134, 135, 136, 137, 138, 139, 140, 141, 142, 143, 144, 145, 146, 147, 148, 149, 150, 151 may be assigned to the transportation or delivery vehicle for space at a given contract specification or utilize another prioritization schema to reserve space or purchase or sell space or trade space at a given specification. In some implementations and embodiments, a vehicle 106 may also be a boat, ship, drone, airplane, truck, rocket, unmanned aircraft, bus or any space utilizing vehicle. In some implementations and embodiments, the virtual toll and congestion or sidewalk community geofence 152 may be assigned or subscribed to for vehicle objects in the geofence. In some embodiments, certain no parking zones 121 may also be designated by the system. In some implementations and embodiments, geofence locations such as 105 and 113 may have longitude, latitude and altitude so that tolls may be managed both above, with higher positive altitude above the surface of the earth and below the surface of the earth with negative altitudes.

FIG. 2 illustrates n some implementations and embodiments, an exemplary network configuration 200. In some embodiments a network of virtual toll and congestion capacity hubs 201, 203, 205, 207, 212, 225 may represent a virtual toll and congestion capacity or virtual sidewalk capacity network of a neighborhood, village, city, county, state, country, continent or even inter-virtual hub networks across geographies. Prior art as well as current inventions carry no methods or data transformations to transform navigation toll and congestion routes or sidewalk routes 202 which are a virtual toll and congestion hub sequence 202 between a series of virtual toll and congestion capacity hubs 201 and 203 or 203 and 212 or even multi-leg combinations such as 201 to 203 and 203 to 212 as a sequence. In some implementations and embodiments, user(s) 213 or the network 214 have input hundreds or thousands or millions or more virtual hubs 201 to form a network topology for toll and congestion capacity virtual hub sequences 241. In some implementations and embodiments, the toll and congestion capacity data transformation to a series of virtual toll and congestion capacity hubs 245, 253 allows for network structure 201, 203, 212, 205, 207, 225, 212 and organization such as a hub and spoke model which is heavily utilized within the airline toll and congestion capacity industry or a plurality of other competing network topologies which are not dependent on road pathways. While hub and spoke toll and congestion capacity systems are common for airplane capacity or bus and train networks, they do not exist for private vehicle networks in an organized manner other than road ways. In some implementations and embodiments, virtual toll and congestion capacity hub topologies 241 over road structures 259 allows for the benefits of public toll and congestion capacity networks to be combined with private toll and congestion networks. In some implementations and embodiments, the virtual toll and congestion capacity hub network 201, 203, 212, 205, 207, 225, 212 has been input into the network 214. In some implementations and embodiments, the topology of the virtual hub network 201, 203, 212, 205, 207, 225, 212 then moves for further data transformation in the community route toll and congestion processor 217 which transforms subsections of the toll and congestion capacity network topology 201, 203, 212, 205, 207, 225, 212 into a virtual hub sequence 241 which represents two addresses 245, 253 along a virtual hug sequence 242 such as Palo Alto, Calif. 245 to San Francisco, Calif. 253 corresponding each virtual hub address 245, 252 with a physical address. Virtual Route Toll and congestion Communities 243 may be one to one, one to two or one to many and any superset or subset combination thereof. The My Toll and congestion Processor 218 further processes virtual hub combination and virtual toll and congestion capacity hub sequences into a specific network members account on the network member database server 222. In some implementations and embodiments, the sequence route processor 221 may connect a plurality of virtual hub sequences 201, 203 205, 207 in a logical order to complete a path combination 201 to 207 for navigation or community object construction. In some implementations and embodiments, community objects may be made from simple direct path routes 202 between two virtual hubs 201 and 203 or multi-virtual hub constructions between two virtual hub sequences 201 to 207 by waypoints of 201 to 203 to 212 to 207 or any combination or superset or subset thereof. In some implementations and embodiments, the virtual route toll and congestion community objects 243 allow attributes to be assigned to the community objects. In some implementations and embodiments, users may be assigned to a plurality or community virtual hub sequence objects 241. In some implementations and embodiments, network members 213 may be assigned to a virtual route toll and congestion community 241 because the user(s) route history on the GPS satellite network 215 suggests the route toll and congestion has overlap with virtual hub route sequences the user has used or queried on various search methods on the system. In some implementations and embodiments the user 213 may use a CPU client 210 that is a visual, audio or other type of computing interface with the network 226 of navigation route communities 243. In some implementations and embodiments, the toll and congestion capacity forward market database server 271 may interface with a processor 219 or sequence toll and congestion processor 221 or my toll and congestion processor 218 or community route toll and congestion object processor 217 to process a plurality of price-time priority queues 300 for transformed toll and congestion capacity unit(s) or other priority schema. In some implementations and embodiments, a plurality of vehicles 258, 257, 256, 254, 246, 247, 248, 249, 250, 251 may be in route between a said first virtual hub 245 and a second said virtual hub 253. In some implementations and embodiments, vehicles 257, 247 may be moving in opposite directions along a route 259. In some implementations and embodiments, a truck 258 may contain a transformed toll and congestion capacity unit(s) or a car 251 may contain a transformed toll and congestion capacity unit(s) or a bus 250 may contain a transformed toll and congestion capacity unit(s) or a plurality of other vehicle types may contain a transformed toll and congestion capacity unit(s) under a specification which is substitutable. In some implementations and embodiments, the virtual toll and congestion hub or community object sequence of waypoints may be reversed from waypoint 245 to waypoint 253 to waypoint 253 to waypoint 245. In some implementations and embodiments, the community route toll and congestion object 241 or community route object sequence 101, 105, 113 may have an infinite series of associated price-time queues 300 whereby any subset or superset comprise a forward market for transformed toll and congestion capacity unit(s), transformed community route object(s) and the associated transformed toll and congestion capacity unit(s). In some implementations and embodiments virtual route communities 241, 101, 121, 141 are transformed data structures that form objects which community users 213 may subscribe, friend, join, follow to more efficiently have news and understanding for the toll and congestion capacity unit transactions as described in U.S. patent application Publication, Ser. No. 15/877,393, “Electronic Forward market exchange for transportation capacity seats and capacity in transportation capacity spaces and vehicles,” filed Jan. 23, 2018, the entirety of which is incorporated by reference herein. In some implementations and embodiments, the Network 226 may use the community toll and congestion processor 217 to interact over the network 226 with other camera devices, visual detection devices, geofence devices, gps satellite networks 215, city and private networks 214 to process 219 images to confirm arrival and drop off of toll and congestion capacity units under a plurality of specifications. In some implementations and embodiments, cities or municipalities may use the network 214, 226 to issue tickets, fines or charges to users who did not pay for the toll and congestion capacity unit in the toll and congestion capacity unit topology 201, 202, 203, 204, 205, 206, 207, 208, 209, 225, 211, 212 against the network member server data 222 community toll and congestion processor 217, my toll and congestion processor 218, general processors 219, general servers 220, sequence toll and congestion processors and memory 224 for a given virtual toll and congestion community object 241.

FIG. 3 illustrates exemplary user price-time priority queue 300 for transacting or matching transformed toll and congestion capacity unit data, participating, transacting and/or trading toll and congestion capacity, representing the transformed toll and congestion capacity unit value as a homogeneous asset specification or sidewalk capacity as a physical forward commodity security between combinations of virtual hubs over various toll and congestion capacity modes. In some implementations and embodiments, user transformed toll and congestion capacity unit(s) or transformed toll and congestion capacity unit(s) associated with route toll and congestion community objects interface 300 includes the following instructions, transformations and elements, or a subset or superset thereof:

exemplary transformed toll and congestion capacity unit price-time priority sell queue 320;

exemplary transformed toll and congestion capacity unit price-time priority buy queue 321;

exemplary transformed toll and congestion capacity unit price priority bucket 305 in the toll and congestion capacity unit buy queue of $5.10;

exemplary transformed toll and congestion capacity unit price priority bucket 306 in the toll and congestion capacity unit buy queue of $5.30;

exemplary transformed toll and congestion capacity unit price priority bucket 310 in the toll and congestion capacity unit buy queue of $5.60;

exemplary transformed toll and congestion capacity unit price priority bucket 314 in the toll and congestion capacity unit sell queue of $5.70;

exemplary transformed toll and congestion capacity unit price priority bucket 315 in the toll and congestion capacity unit sell queue of $5.80;

exemplary transformed toll and congestion capacity unit price priority bucket 316 in the toll and congestion capacity unit sell queue of $6.60;

exemplary transformed toll and congestion capacity unit price-time priority buy price 304 in the first time position of the price priority bucket 305 of $5.10;

exemplary transformed toll and congestion capacity unit price-time priority buy price 303 in the second time position of the price priority bucket 305 of $5.10;

exemplary transformed toll and congestion capacity unit price-time priority buy price 302 in the third time position of the price priority bucket 305 of $5.10;

exemplary transformed toll and congestion capacity unit price-time priority buy price 307 in the first time position of the price priority bucket 306 of $5.30;

exemplary transformed toll and congestion capacity unit price-time priority buy price 309 in the first time position of the price priority bucket 310 of $5.60;

exemplary transformed toll and congestion capacity unit price-time priority buy price 308 in the second time position of the price priority bucket 310 of $5.60;

exemplary transformed toll and congestion capacity unit price-time priority sell price 311 in the first time position of the price priority bucket 314 of $5.70;

exemplary transformed toll and congestion capacity unit price-time priority sell price 312 in the second time position of the price priority bucket 314 of $5.70;

exemplary transformed toll and congestion capacity unit price-time priority sell price 313 in the third time position of the price priority bucket 314 of $5.70;

exemplary transformed toll and congestion capacity unit price-time priority sell price 318 in the first time position of the price priority bucket 315 of $5.80;

exemplary transformed toll and congestion capacity unit price-time priority sell price 319 in the second time position of the price priority bucket 315 of $5.80;

exemplary transformed toll and congestion capacity unit price-time priority sell price 317 in the first time position of the price priority bucket 316 of $6.60;

exemplary transformed toll and congestion capacity unit price time priority limit order book (“LOB”) 325 is represented by the vector q(t) 301, such that the i-th coordinate for i>0, q_(i)(t), is the number of sell limit orders of transformed toll and congestion capacity units that are waiting in the LOB at time t a price iδ (δ is the price unit tick size of the transformed toll and congestion capacity unit), the number of buy limit orders for transformed toll and congestion capacity units at iδ are represented with a negative sign q_(i)(t);

exemplary benchmark price 326 of all sell limit orders at time t are computed as s(t)=s(q(t))=min (min {0<iδ: q_(i)(t)>0}), if q_(i)(t) is less than or equal to 0 for all i>0, then s(q (t))=infinity;

exemplary benchmark price 327 of all buy limit orders at time t are computed as b(t)=b (q (t))=max (max{iδ>0: q_(i)(t)<0}), if q_(i)(t) is greater than or equal to 0 for all i>0, then b(q(t))=negative infinity;

exemplary order match 328 in the transformed toll and congestion capacity unit limit order book where s(t)=b(t), which then moves the method and system to the matched transformed toll and congestion capacity unit limit order confirmation and delivery process;

exemplary limit order book status of no order match 329, where s(t)>b(t);

exemplary limit order book i-th q_(i)(t) element 330 of LOB is cancelled, remove from queue;

exemplary i-th qi(t) element is a new transformed toll and congestion capacity unit order 331 in LOB, insert into respective limit order buy queue 321 or limit order sell queue 320 with priority of price, then time into the price time priority queues 300.

In some implementations and embodiments, the price-time priority queue 300 for transformed toll and congestion capacity units may be assigned to a commute community object 241 which is a waypoint sequence of transformed toll and congestion capacity units. In some implementations and embodiments, the price-time priority queue 300 may be assigned to two waypoints as a commute community object 241 or the price-time prior queue 300 may be assigned to a commute community waypoint object sequence of many waypoints 203 to 205 to 207 to 212 which have been added together to form one continuous toll and congestion community object 241 and respective price-time priority queue for transformed toll and congestion capacity units through processing instructions from the Community Toll and congestion Route Processor 217 and Sequence Toll and congestion Route Processor 221 via the network(s) 226 and 214 and 215. In some implementations and embodiments, the limit order book 301 vector may be assigned to a specific date and time for the commute community waypoint object which is a forward market price for transformed toll and congestion capacity unit(s) 271 and commute community waypoint object(s) 241. In some implementations and embodiments, a specific transformed toll and congestion capacity unit price-time priority queue limit buy order 304 with a specific price stamp bucket 305 of $5.10, may be cancelled, if the 304 order is cancelled, the 303 price-time priority limit order book buy queue price then moves to the higher price-time priority queue position of 304 and price-time priority price of 302 moves to position 303. In some implementations and embodiments, the price-time priority limit order sell price 319 of price-time priority bucket price 315 of $5.80 may be cancelled, if 319 price-time priority of the transformed toll and congestion capacity unit is cancelled, then order 317 moves to a higher position in the overall transformed toll and congestion capacity queue 320 even though the limit order book price 317 remains in the price bucket of 316 which is $6.60. In some implementations and embodiments, price-time priority insertion may occur where a new order is inserted into either the transformed toll and congestion capacity unit buy queue 320 or transformed toll and congestion capacity unit sell queue 321. In some implementations and embodiments, by example but not limiting by example, a new price-time limit order for a transformed toll and congestion capacity unit may be inserted as a sell order at a price of $5.70 at position 313 which would then assume order 312 was also at a price of $5.70 and that order 312 was placed with a time that was before order 313 was placed. In the aforementioned example of the price-time order insertion of 313, price-time orders of 319, 318 and 317 have moved lower in their relative position even though they remain in distinctly different price buckets of 315 and 316 respectively as the price-time priority queue 300, price is first priority, then time stamp in the price-time priority queue 300 for transformed toll and congestion capacity units.

In some implementations and embodiments, the lowest selling price s(t) 326 may equal the highest buying price b(t) 327, in which case the highest transformed toll and congestion capacity unit buy queue price bucket 310 is equal to the lowest transformed toll and congestion capacity unit sell queue 320 selling bucket price 314. In the example 300 of the limit order book 301, but not limiting by example, the highest transformed unit buy price 310 of $5.60 is lower than the lowest toll and congestion capacity unit sell queue 320 lowest selling bucket 314 of $3.70 so no match occurs because s(t)>b(t) 329. In some implementations and embodiments, many order insertions 331 or order cancellations 330 may occur for transformed toll and congestion capacity units from the toll and congestion capacity forward market database server 271 associated with community objects which are series of waypoints 241.

In some implementations and embodiments, the LOB 300 for transformed toll and congestion capacity units may contain many different types of instruction structures and specifications such as limit orders 720, market orders 720, market if touched orders 720, snap market orders 720, snap mid orders 720, snap to primary orders 720, peg to benchmark orders 720, or adaptive custom orders 720 which are custom customer designed instructions which are all standard order types for anyone skilled in the art of markets. In some implementations and embodiments, the LOB 300 for transformed toll and congestion capacity units may also contain instructions for order times such as good for the day 710, good till cancelled 710, immediate or cancel 710, good till date 710, day till cancelled 710 or a plurality of additional custom instructions for the timing of the order of the transformed toll and congestion capacity unit in the LOB 300 that is associate with a commute community object 241. In some implementations and embodiments, a plurality of additional instructions and specifications may also be unique to each transformed toll and congestion capacity unit LOB 300 such as automobile mode 811, air mode 812, autonomous vehicle mode 813, bike mode 814, boat mode 815, bus mode 816, drone mode 817, limo mode 818, motorcycle mode 819, moped mode 820, shuttle mode 821, spaceship mode 822, subway mode 823, taxi mode 824, scooter mode, eBike mode, eScooter mode, train mode 825, fastest optimized mode 826, which may combine many modes 810 or a single mode 810 for a waypoint commute community object 241 or waypoint community sequence 201 to 203 to 205 to 212 to 207 of many commute communities 241.

In some implementations and embodiments, the LOB 300 may be assigned to transformed toll and congestion capacity unit packages 828 that have associated commute community objects 241. In some implementations and embodiments, the LOB 300 for transformed toll and congestion capacity units may be assigned to cargo 829 such as a trailer of a rig or container of a boat or container on a truck or any type of cargo that takes up the space of a transformed toll and congestion capacity unit. In some implementations and embodiments, the LOB 300 may even be assigned to the virtual transformed toll and congestion capacity unit 830 which would be space along a packet moving medium such as a telecom pipeline, satellite telecom or wireless telecom that moves packets of data which are transformed toll and congestion capacity units parked in storage on the cloud.

In some implementations and embodiments, the toll and congestion capacity unit may be assigned to a plurality of other priority queues for trading purposes including but not limited to various blockchain sequences tied to the toll and congestion capacity unit over a distributed ledger on the community toll and congestion processor 217 or server 220 or sequence toll and congestion processor 221 or toll and congestion forward market database server 271.

FIG. 4 illustrates exemplary user interfaces 210 for participating, transacting and/or trading toll and congestion capacity as a physical forward data transformed toll and congestion capacity unit commodity or security between combinations of virtual hubs which may be community objects 241 over various toll and congestion capacity modes. In some implementations and embodiments, user interface 210 includes the following elements, or a subset or superset thereof:

Exemplary virtual toll and congestion hub combination 311;

Exemplary virtual hub origin/from location 410 with users 412 within the virtual hub location 310;

Exemplary specification summary of the market, level of service and time of delivery commencement 427, in this particular embodiment the GUI 210 has moved to an international virtual market hub combination market such as within London;

Exemplary mode of toll and congestion capacity type 430;

Exemplary transaction summary of the last trade auction quantity and price 428 in the local currency or another currency set by the user 110;

Exemplary virtual toll and congestion hub destination/to location 422 and user who is being delivered on the toll and congestion capacity or freight capacity unit 423;

Exemplary bid/buy quantity title header 415 for an exemplary virtual toll and congestion capacity hub market;

Exemplary bid/buy price title header 416 for an exemplary virtual toll and congestion capacity hub market;

Exemplary offer/sell price title header 419 for an exemplary virtual toll and congestion capacity hub market;

Exemplary offer/sell quantity title header 426 for an exemplary virtual toll and congestion capacity hub market;

Exemplary bid/buy quantity 414 for the best bid quantity for the associated LOB 300 from a plurality of users 110 for an exemplary respective toll and congestion capacity virtual hub combination that has undergone a plurality of data transformations in the method 411;

Exemplary bid/buy quantity 413 for the second-best bid quantity for the associated LOB 300 from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight capacity virtual hub combination that has undergone a plurality of data transformations in the method 411;

Exemplary bid/buy price 418 for the best bid price for the associated LOB 300 from a plurality of users 110 for an exemplary respective toll and congestion capacity virtual hub combination that has undergone a plurality of data transformations in the method 411;

Exemplary bid/buy price 417 for the second-best bid price for the associated LOB 300 from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight capacity virtual hub combination that has undergone a plurality of data transformations in the method 411;

Exemplary offer/sell price 421 for the best offer price for the associated LOB 300 from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight capacity virtual hub combination that has undergone a plurality of data transformations in the method 411;

Exemplary offer/sell price 420 for the second-best offer price for the associated LOB 300 from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight capacity virtual hub combination that has undergone a plurality of data transformations in the method 411;

Exemplary offer/sell quantity 425 for the best offer quantity for the associated LOB 300 from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight capacity virtual hub combination that has undergone a plurality of data transformations in the method 411;

Exemplary offer/sell quantity 424 for the second-best offer quantity for the associated LOB 300 from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight capacity virtual hub combination that has undergone a plurality of data transformations in the method 411;

Exemplary safety dispatch “911” button 429 to enact video and audio recording of the user 110 environment and dispatch of that information to authorities.

Exemplary hamburger menu button 270 to move back to menu options and settings away from the participation, transaction, trading GUI 210 embodiment.

In some implementations and embodiments the user 110 may enter a transaction quantity and price for transformed toll and congestion capacity or freight capacity unit securities to participate, transact and/or trade by the GUI 210 detecting user 110 contact with a bid/buy price 418 or offer/sell price 421. The GUI 210 detects user 110 contact with any of the GUI 210 buttons which have been aforementioned. The GUI 210 may detect user contact 110 with any of the GUI 210 buttons 418, 417, 420, 421 or user 110 voice interface with the application 210 method. Upon user 110 contact with buttons on the GUI 210, instructions are instantiated which allows the user 110 to change the specifications of the respective virtual hub combination 411. A plurality of prices and markets may be presented based on a plurality of contract specifications. In some implementations and embodiments, the best bid/buy price 418 may be moving up in price or down in price depending on the market conditions at any given time. In some implementations and embodiments the last auction trade or last transacted price for a given specification is listed to help the user 110 understand how the market is moving so that the user 110 may submit a competitive offer/selling price 421 or bid/buying price 414. In some implementations and embodiments, users 110 may adjust settings of the GUI 210 to show more bid/buying prices 417 or more offer/selling prices 420. In some implementations and embodiments the matrix of market quantities and prices 413, 414, 415, 416, 417, 418, 419, 420, 421, 424, 425, 426 may be referred to as market depth in the GUI 210 embodiment. In some implementations and embodiments the number of users 110 may be displayed as user icons 412 or 423 for the amount of people logged in which desire to transact, trade or participate in a given virtual hub 410 to virtual hub 422 combination auction. In some implementations and embodiments, users 110 may select the toll and congestion capacity mode 430 such that the user allows a market for only one form of transformed toll and congestion capacity as a commodity or security or the user 110 may allow the system to show multiple forms of transformed toll and congestion capacity between two virtual toll and congestion capacity hubs 410, 411, 422. In some implementations and embodiments the GUI 210 may detect a user 110 selecting the 911 button 429 which may activate voice and video recording functions on the mobile or stationary device 111 and transmit the data with a confirmation from the user 110 to the authorities to provide enhanced security while participating, transacting or trading forward transformed toll and congestion capacity or freight as a commodity or security. In some implementations and embodiments the user may toggle between the GUI 210 market view screen in FIG. 4 and other menu 270 options and settings by the user 110 selecting the hamburger button 270 and the GUI 210 detecting the user 110 input or contact. In some implementations and embodiments the GUI 210 may instantiate instructions in the memory of the mobile computing device 111 which then transmits toll and congestion capacity or freight capacity data through the network 140 or wireless GPS network 150 to call upon instruction routines and instruction sub-routines on the toll and congestion capacity forward market database server 130, virtual hub database server 120, network member database server 160, no arbitrage condition database server 180 and/or instructions in the memory of the cloud and local CPUs 190 which all interface together to make one system which may deliver toll and congestion capacity or freight capacity units to users 110 from and to a plurality of virtual hubs 410, 422 with a plurality of specifications 427 at specific market prices.

FIG. 5 illustrates an exemplary user interface 210 for listing timing specifications 510 on a portable multifunction device in accordance with some embodiments. In some implementations and embodiments, user interface 210 includes the following elements, or a subset or superset thereof:

Origin/From virtual toll and congestion hub timing specification (a data transformation) 510;

specification of quality of toll and congestion capacity (a data transformation) 520;

destination/To virtual hub (a data transformation) 530;

setting button 540 to transmit the timings 510 and quality specification grade 520 (a data transformation);

hamburger button 270 to instruct the GUI 210 to take the user 110 to the menu screen.

In some implementations and embodiments, the user 110 may select a plurality of timing options in the timing selection specification 510. The timing specification constraint may be the time at which the transformed toll and congestion capacity or freight toll and congestion capacity unit security departs from the origin/from virtual hub 410. As in any commodity market, if a user 110 is late and they have purchased the toll and congestion capacity unit, the user must still pay for the toll and congestion capacity or freight capacity unit regardless if the user 110 is present at the time of departure or not. The user has the option if they know they will be late to sell back the toll and congestion capacity or freight toll and congestion capacity unit to the market at the then current price. Accordingly, for the purpose of example, but not limiting by example, if a user 110 bought a transformed toll and congestion capacity unit security for £9.90 421 and the user 110 realized they would be late for the 8 am toll and congestion departure specification 427, then the user 110 may either pay for the toll and congestion capacity unit even though the user 110 was present and did not take delivery of the toll and congestion capacity unit security, or the user 110 may preemptively sell back the toll and congestion capacity unit security to the market at the then current bid price 418. The user 110 would then have offset their obligation in a timely manner and another user 110 on the network 140, 160 may then purchase the available toll and congestion capacity or freight toll and congestion capacity unit security. By eliminating the initial obligation by an creating an offset obligation, the additional data transformation concepts such as cost of cover, liquidated damages or force majeure are not employed by the method. In some implementations and embodiments, virtual toll and congestion capacity or freight hub combination units may or may not have the available liquidity if the user 110 were to wait too long before delivery of the toll and congestion capacity unit to make an adjustment and therefore may need to take delivery even if they are not present. In some implementations and embodiments, the user 110 may select a grade specification 520. For the purpose of example, but not limiting by example, a plurality of specification grades may exist, such as “premium” which may be defined by certain classes of toll and congestion capacity units and/or certain quality levels. Similarly, for the purpose of example, but not limiting by example, a plurality of specification grades may exist such as “intermediate” or “basic” which may be defined by certain classes of toll and congestion capacity or freight capacity unit securities and/or certain quality levels. In some implementations and embodiments, many variations of specification grades may be utilized in a priority grid structure. In some implementations and embodiments, the user 110 may select the destination/to virtual hub 530 to change the virtual toll and congestion hub combination. In some implementations and embodiments, the user 110, may contact the “set” button 540 to transmit the transformed toll and congestion capacity unit security specification data by using the GUI 210 which may instantiate instructions in the memory of the mobile computing device which then transmits toll and congestion capacity data through the network 160 or wireless GPS network to call upon instruction routines and instruction sub-routines on the toll and congestion capacity forward market database server 163, virtual toll and congestion unit queue hub database server 163 and processor 162, network member database server 222, map routing servers 220 and/or instructions in the memory of the cloud and local CPUs 164 which all interface together to make one system which may deliver transformed toll and congestion capacity unit securities or unitized objects to users 110 from and to a plurality of virtual hubs 410, 422 with a plurality of specifications at specific market prices.

FIG. 6 illustrates an exemplary user interface 210 for selecting the term transformation specification 610 on a portable multifunction device in accordance with some embodiments. In some implementations and embodiments, user interface 210 includes the following elements, or a subset or superset thereof:

term specification options (a data transformation) 610;

specification of quality of toll and congestion capacity or freight toll and congestion capacity (a data transformation) 620;

destination/to virtual toll and congestion hub (a data transformation) 630;

setting button 640 to transmit the term 610 and quality toll and congestion specification grade (a data transformation) 620;

calendar button 650 to select specification start dates and end dates for a plurality of virtual toll and congestion capacity or freight hub combinations (a data transformation);

hamburger button 270 to instruct the GUI 210 to take the user 110 to the menu screen.

In some implementations and embodiments, the term specification 610 may be used to participate, transact and/or trade in a specific virtual toll and congestion hub combination for a specific time period specification. Users 110 may set the term to daily, weekly, monthly, annual, weekdays, weekends, specific days such as Monday, Tuesday, Wednesday, Thursday, Friday, Saturday, Sunday or any combination of term selections the user 110 sets as relevant for participating, transacting or trading in the transformed toll and congestion capacity or freight toll and congestion capacity unit securities market. Not limiting by example, but for use of illustrating a possible subset of term selections, the user 110 may select “weekdays” 610 during a specific calendar time period 650 of a given year. In some implementations and embodiments, specific time start dates and end dates may be set by the user with the calendar button 650. In some implementations and embodiments a user 110 may select “Mondays” 610 within a specification date window 650 (a data transformation). In some implementations and embodiments, the user 110 may select “weekends” 610 during a specification calendar window of dates 650 (a data transformation). In some implementations and embodiments, the user 110, may contact the “set” button 640 to transmit the transformed toll and congestion capacity or freight toll and congestion capacity unit specification data by using the GUI 210 which may instantiate instructions in the memory of the mobile computing device which then transmits toll and congestion capacity data through the network 214 or wireless GPS network 215 to call upon instruction routines and instruction sub-routines on the toll and congestion capacity forward market database server 271, virtual toll and congestion hub database server 223, network member database server 222, map routing servers 220, no arbitrage condition database server 280 and/or instructions in the memory of the cloud and local CPUs 219 which all interface together to make one system which may deliver toll and congestion capacity units to users 110 from and to a plurality of virtual toll and congestion hubs 410, 422 with a plurality of specifications at specific market prices.

FIG. 7 illustrates an exemplary user interface 210 for selecting order time in force order types 710 (a data transformation) as well as order types 720 (a data transformation) on a portable multifunction device in accordance with some embodiments. In some implementations and embodiments, user interface 210 includes the following elements, or a subset or superset thereof:

order time in force specification options (a data transformation) 710;

order type specification options (a data transformation) 720;

setting button 740 to transmit the order time in force specification 710 and order type specification option 720 (a data transformation);

hamburger button 270 to instruct the GUI 210 to take the user 110 to the menu screen.

In some implementations and embodiments, user interface 210 may be used by the user 110 to select a plurality of order time in force 710 specifications. In some implementations and embodiments, order time in force selections 710 may include a subset or superset thereof: day (DAY) order 710; good till cancelled order (GTC) 710; immediate or cancel order (IOC) 710; good till date order (GTD) 710; day till cancelled order (DTC) 710. Order time in force 710 specifications may be used to designate how long a user 110 order may be valid. In some implementations and embodiments, the GUI 210 may display the definitions of a plurality of order time in force 710 characteristics so that the user 110 may select the appropriate order time in force 710 specification for the toll and congestion capacity or freight toll and congestion capacity unit that the user 110 may participate, transact and/or trade. In some implementations and embodiments, the user interface 210 may be used to select the order type 720 specifications. In some implementations and embodiments, order type selections 720 may include a subset or superset thereof: Limit 720, Market 720, Market if Touched (MIT) 720; Snap to Market 720; Snap to Mid 720; Snap to primary 720; Peg to benchmark 720; adaptive custom 720. In some implementations and embodiments, the GUI 210 may display the definitions of a plurality of order types 720 characteristics so that the user 110 may select the appropriate order type 720 specification for the toll and congestion capacity or freight capacity unit that the user 110 may participate, transact and/or trade. In some implementations and embodiments, the user 110, may contact the “set” button 740 to transmit the toll and congestion capacity or freight toll and congestion capacity unit specification mode data by using the GUI 210 which may instantiate instructions in the memory of the mobile computing device which then transmits toll and congestion capacity data through the network 214 or wireless GPS network 215 to call upon instruction routines and instruction sub-routines on the toll and congestion capacity forward market database server 271, virtual toll and congestion hub database server 223, network member database server 222, map routing servers 220, no arbitrage condition database server 280 and/or instructions in the memory of the cloud and local CPUs 219 which all interface together to make one system which may deliver toll and congestion capacity units to users 110 from and to a plurality of virtual toll and congestion hubs 410, 422 with a plurality of specifications at specific market prices.

FIG. 8 illustrates an exemplary user interface 210 for selecting virtual hub toll and congestion capacity unit modes 810 (a data transformation) on a portable multifunction device in accordance with some embodiments. In some implementations and embodiments, user interface 210 includes the following elements, or a subset or superset thereof:

virtual hub toll and congestion capacity unit modes 810 (a data transformation);

setting button 840 to transmit the virtual hub toll and congestion capacity unit modes 810;

hamburger button 270 to instruct the GUI 210 to take the user 110 to the menu screen.

In some implementations and embodiments, user interface 210 may be used by the user 110 to select a plurality of virtual hub transformed toll and congestion capacity unit security modes 810 specifications. In some implementations and embodiments, virtual hub toll and congestion capacity unit mode selections 810 may include a subset or superset thereof: Automobile 811; air 812; autonomous vehicle 813; bike 814; boat 815; bus 816; drone 817; limo 818; motorcycle 819; moped 820; shuttle 821; space 822; subway 823; taxi 824; train 825; fastest optimized 826; cheapest route 827; packages 828; cargo 829; virtual 830; eScooter; eBike, or other modes. In some implementations and embodiments, virtual hub toll and congestion capacity unit modes are simply that a user 110 would have a virtual toll and congestion capacity or freight capacity unit seat in an automobile or an airplane as examples, but not limiting by example. In some implementations and embodiments, the user 110 may bid on cargo 829 or package capacity 828 in any mode or multi-modal of transformed toll and congestion capacity or freight capacity between a combination of virtual toll and congestion capacity hub locations. In some implementations and embodiments, the user 110 may use one or multiple modes of toll and congestion capacity between a combination of virtual toll and congestion capacity hub capacity points. In some implementations and embodiments, the user 110, may contact the “set” button 840 to transmit the transformed toll and congestion capacity or freight toll and congestion capacity unit specification mode data by using the GUI 210 which may instantiate instructions in the memory of the mobile computing device which then transmits toll and congestion capacity data through the network 214 or wireless GPS network 215 to call upon instruction routines and instruction sub-routines on the toll and congestion capacity forward market database server 271, virtual toll and congestion hub database server 223, network member database server 222, map routing servers 220, no arbitrage condition database server 280 and/or instructions in the memory of the cloud and local CPUs 219 which all interface together to make one system which may deliver toll and congestion capacity units to users 110 from and to a plurality of virtual toll and congestion hubs 410, 422 with a plurality of specifications at specific market prices.

FIG. 9 illustrates an exemplary user interface 210 for identifying the distance the user 110 is from the virtual hub from a map and distance perspective on a portable multifunction device in accordance with some embodiments. In some implementations and embodiments, user interface 210 includes the following elements, or a subset or superset thereof:

virtual hub toll and congestion capacity unit pick up display 910;

virtual hub toll and congestion capacity unit pick up address 920;

virtual hub toll and congestion capacity unit drop off address 930;

virtual hub toll and congestion capacity pick-up target zone 960;

virtual hub toll and congestion capacity drop-off target zone 950;

setting button 940 to transmit the virtual hub toll and congestion capacity unit addresses 920, 930;

hamburger button 270 to instruct the GUI 210 to take the user 110 to the menu screen.

In some implementations and embodiments, user interface 210 may be used by the user 110 to select a plurality of virtual hub toll and congestion capacity unit address 910 specifications. In some implementations and embodiments, virtual hub toll and congestion capacity or freight toll and congestion capacity unit address selections 910 may include a subset or superset thereof: virtual hub pick up address 920; virtual hub drop off address 930. In some implementations and embodiments, virtual hub toll and congestion capacity unit addresses 920 and 930 may be changed before delivery of a virtual toll and congestion capacity unit. The user interface map and address tool 910 displays the users 110 distance from the address of the virtual toll and congestion capacity or freight hub as well as a map to assist the user 110 in finding the location of the virtual toll and congestion capacity hub. In some implementations and embodiments, user interface 210 displays the virtual hub pick up zone 960 on a map in context to the user's 110 location. In some implementations and embodiments, user interface 210 displays the virtual hub drop off zone 950 on a map in context to the user's 110 location. In some implementations and embodiments, the user 110, may contact the “set” button 940 to transmit the toll and congestion capacity unit specification mode data by using the GUI 210 which may instantiate instructions in the memory of the mobile computing device which then transmits toll and congestion capacity data through the network 214 or wireless GPS network 215 to call upon instruction routines and instruction sub-routines on the toll and congestion capacity forward market database server 271, virtual toll and congestion hub database server 223, network member database server 222, map routing servers 220, no arbitrage condition database server 280 and/or instructions in the memory of the cloud and local CPUs 219 which all interface together to make one system which may deliver toll and congestion capacity units to users 110 from and to a plurality of virtual toll and congestion hubs 410, 422 with a plurality of specifications at specific market prices.

FIG. 10 illustrates an exemplary user interface 210 for identifying the constraints and no arbitrage settings 1010 the user 110 selects on a portable multifunction device in accordance with some embodiments (multiple data transformations). In some implementations and embodiments, user interface 210 includes the following elements, or a subset or superset thereof:

constraint and no arbitrage settings 1010 (a data transformation);

setting button 1040 to transmit the virtual hub toll and congestion capacity constraints and no arbitrage settings;

hamburger button 270 to instruct the GUI 210 to take the user 110 to the menu screen.

In some implementations and embodiments, user interface 210 may be used by the user 110 to select a plurality of virtual hub toll and congestion capacity constraint and no arbitrage settings 1010. In some implementations and embodiments, virtual hub toll and congestion capacity unit constraint and no arbitrage selections 1010 may include a subset or superset thereof: cheapest route 1011 (a data transformation); single mode 1012 (a data transformation); multi-mode 1013 (a data transformation); fastest route 1014 (a data transformation); most scenic 1015 (a data transformation); highest rating 1016 (a data transformation); most available 1017 (a data transformation); highest volume 1018 (a data transformation); most frequent 1019 (a data transformation); service level 1020 (a data transformation); security and safety 1021 (a data transformation). In some implementations and embodiments, the “cheapest route setting” 1011 instantiates instructions in the memory of the CPU 190 to complete a standard cost minimization linear program to assist the user 110 to complete the toll and congestion capacity unit between two virtual hubs with the lowest cost. In some implementations and embodiments, the “single mode” 1012 instantiates instructions in the memory of the CPU 190 to set a constraint for the user 110 to complete the toll and congestion capacity unit between two virtual hubs with the only one mode of toll and congestion capacity. In some implementations and embodiments, the “multi mode” 1013 instantiates instructions in the memory of the CPU 164 to set a constraint for the user 110 to complete the toll and congestion capacity unit between two virtual hubs with more than one mode of toll and congestion capacity. In some implementations and embodiments, the “fastest route” 1014 instantiates instructions in the memory of the CPU 164 to complete standard linear programming equation to minimize travel time for the user 110 to complete the toll and congestion capacity unit between two virtual hubs with the shortest time. In some implementations and embodiments, the settings 1010 may set instructions for the price based navigation routing index and GUI presentation on the user(s) 110 interface 111. In some implementations and embodiments, the “most scenic” 1015 instantiates instructions in the memory of the CPU 164 to complete an algorithm with the highest ratings for scenery to assist the user 110 to complete the transformed toll and congestion capacity unit between two virtual hubs with highest scenery rating. In some implementations and embodiments, the “highest rating” 1016 instantiates instructions in the memory of the CPU 164 to complete a rating algorithm to assist the user 110 to complete the toll and congestion capacity unit between two virtual hubs with the highest rating. In some implementations and embodiments, the “most available” 1017 instantiates instructions in the memory of the CPU 164 to complete a algorithm to search for the route with the most open toll and congestion capacity units to assist the user 110 to complete the toll and congestion capacity unit between two virtual toll and congestion hubs with the most available open seats or open toll and congestion capacity units. In some implementations and embodiments, the “highest volume” 1018 instantiates instructions in the memory of the CPU 164 to complete an algorithm to select the toll and congestion route with the highest volume of participants to assist the user 110 to complete the transformed toll and congestion capacity unit between two virtual toll and congestion hubs with the largest number of users 110. In some implementations and embodiments, the “most frequent” 1019 instantiates instructions in the memory of the CPU 164 to complete most frequent route analysis from a timing constraint perspective to assist the user 110 to complete the toll and congestion capacity unit between two virtual toll and congestion hubs with the most frequent departures. In some implementations and embodiments, the “service level” 1020 instantiates instructions in the memory of the CPU 164 to align the constraint to select the service level to assist the user 110 to complete the toll and congestion capacity unit between two virtual hubs with the correct level of service. In some implementations and embodiments, the “security and safety” 1021 instantiates instructions in the memory of the CPU 164 to run safety and security algorithms on the user's 110 based on block chain performance of drivers and riders to assist the user 110 to complete the toll and congestion capacity unit between two virtual hubs with the highest level of safety and security. In some implementations and embodiments, the “group restricted” 1022 instantiates instructions in the memory of the CPU 190 to run grouping limitation algorithms on the user's 110 market auction based on limiting the pool of toll and congestion landing drivers and toll and congestion landing riders or toll and congestion landing freight providers and toll and congestion landing shippers to assist the user 110 to complete the toll and congestion capacity or freight toll and congestion capacity unit between two virtual hubs with a limit on the pool of available users. In some implementations and embodiments, a plurality of settings which transform the data may be sequenced for presenting as a transformed market 400 or as a transformed market as a layer on a navigation system with indexed toll and congestion routes based on price 4200. A user(s) 110 pool for group restricted 1022 (a data transformation) settings may limit the user pool displayed by email, security, sex, rating or a plurality of other restrictions. In some implementations and embodiments, the user 110, may contact the “set” button 1040 to transmit the toll and congestion capacity or freight capacity unit security specification settings mode data by using the GUI 210 which may instantiate instructions in the memory of the mobile computing device which then transmits toll and congestion capacity data through the network 214 or wireless GPS network 215 to call upon instruction routines and instruction sub-routines on the toll and congestion capacity forward market database server 271, virtual toll and congestion hub database server 223, network member database server 222, map routing servers 220, no arbitrage condition database server 280 and/or instructions in the memory of the cloud and local CPUs 219 which all interface together to make one system which may deliver toll and congestion capacity units to users 110 from and to a plurality of virtual toll and congestion hubs 410, 422 with a plurality of specifications at specific market prices.

FIG. 11 illustrates exemplary user interfaces 210 for participating, transacting and/or trading transformed toll and congestion capacity or toll and congestion freight as a physical forward commodity or security between combinations of virtual hubs over various toll and congestion capacity modes. In some implementations and embodiments, user interface 210 includes the following elements, or a subset or superset thereof:

exemplary virtual hub combination 1111;

exemplary virtual hub origin/from location 1110 with users 1112 within the virtual toll and congestion hub location 1110;

exemplary specification summary of the market, level of service and time of delivery commencement 1127;

exemplary mode of air toll and congestion capacity or air toll and congestion freight capacity type 1130;

exemplary transaction summary of the last trades quantity and price 1128;

exemplary virtual hub destination/to location 1122 and user who is being delivered on the toll and congestion capacity unit 1123;

exemplary bid/buy quantity title header 1115 for an exemplary virtual toll and congestion capacity hub market;

exemplary bid/buy price title header 1116 for an exemplary virtual toll and congestion capacity or toll and congestion freight hub market;

exemplary offer/sell price title header 1119 for an exemplary virtual toll and congestion capacity or freight hub market;

exemplary offer/sell quantity title header 1126 for an exemplary virtual toll and congestion capacity or freight hub market;

exemplary bid/buy quantity 1114 for the best bid quantity from a plurality of users 110 for an exemplary respective toll and congestion capacity or toll and congestion freight capacity virtual hub combination that has undergone a plurality of data transformations in the method 1111;

exemplary bid/buy quantity 1113 for the second-best bid quantity from a plurality of users 110 for an exemplary respective toll and congestion capacity or toll and congestion freight capacity virtual hub combination that has undergone a plurality of data transformations in the method 1111;

exemplary bid/buy price 1118 for the best bid price from a plurality of users 110 for an exemplary respective toll and congestion capacity or toll and congestion freight capacity virtual hub combination that has undergone a plurality of data transformations in the method 1111;

exemplary bid/buy price 1117 for the second-best bid price from a plurality of users 110 for an exemplary respective toll and congestion capacity or toll and congestion freight capacity virtual hub combination that has undergone a plurality of data transformations in the method 1111;

exemplary offer/sell price 1121 for the best offer price from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight capacity virtual hub combination that has undergone a plurality of data transformations in the method 1111;

exemplary offer/sell price 1120 for the second-best offer price from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight capacity virtual hub combination that has undergone a plurality of data transformations in the method 1111;

exemplary offer/sell quantity 1125 for the best offer quantity from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight capacity virtual hub combination that has undergone a plurality of data transformations in the method 1111;

Exemplary offer/sell quantity 1124 for the second-best offer quantity from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight capacity virtual hub combination that has undergone a plurality of data transformations in the method 1111;

exemplary safety dispatch “911” button 1129 to enact video and audio recording of the user 110 environment and dispatch of that information to authorities;

exemplary hamburger menu button 270 to move back to menu options and settings away from the participation, transaction, trading auction GUI 210 embodiment.

In some implementations and embodiments the user 110 may enter a transaction quantity and price for transformed toll and congestion capacity or toll and congestion freight capacity unit securities to participate, transact and/or trade by the GUI 210 detecting user 110 contact or audio interface with a bid/buy price 1118 or offer/sell price 1121. The GUI 210 detects user 110 contact with any of the GUI 210 buttons which have been aforementioned. Upon user 110 contact or audio interface with buttons on the GUI 210, instructions are instantiated which allow the user 110 to change the specifications of the respective virtual toll and congestion hub combination 1111. A plurality of prices and markets may be presented based on a plurality of contract specifications. In some implementations and embodiments, the best bid/buy price 1118 may be moving up in price or down in price depending on the market conditions at any given time. In some implementations and embodiments the last trade or last transacted price for a given specification is listed to help the user 110 understand how the market is moving so that the user 110 may submit a competitive offer/selling price 1121 or bid/buying price 1118. In some implementations and embodiments, users 110 may adjust settings of the GUI 210 to show more bid/buying prices 1117 or more offer/selling prices 1120. In some implementations and embodiments the matrix of market quantities and prices 1113, 1114, 1115, 1116, 1117, 1118, 1119, 1120, 1121, 1124, 1125, 1126 may be referred to as market depth in the GUI 210 embodiment. In some implementations and embodiments the number of users 110 may be displayed as user icons 1112 or 1123 for the amount of people logged in which desire to transact, trade or participate in a given virtual toll and congestion hub 1110 to virtual toll and congestion hub 1122 combination. In some implementations and embodiments, users 110 may select the toll and congestion capacity mode 1130 such that the user allows a market for only one form of toll and congestion capacity as a commodity or the user 110 may allow the system to show multiple forms of toll and congestion capacity between two virtual toll and congestion capacity hubs 1110, 1111, 1122. In some implementations and embodiments the GUI 210 may detect a user 110 selecting the 911 button 1129 which may activate voice and video recording functions on the mobile or stationary device 210 and transmit the data with a confirmation from the user 110 to the authorities to provide enhanced security while participating, transacting or trading transformed forward toll and congestion capacity as a commodity or security. In some implementations and embodiments the user may toggle between the GUI 210 market view screen in FIG. 3 and other menu 270 options and settings by the user 110 selecting the hamburger button 270 and the GUI 210 detecting the user 110 input or contact or audio instruction. In some implementations and embodiments the GUI 210 may instantiate instructions in the memory of the mobile computing device 210 which then transmits toll and congestion capacity or freight capacity data through the network 214 or wireless GPS network 215 to call upon instruction routines and instruction sub-routines specification mode data by using the GUI 210 which may instantiate instructions in the memory of the mobile computing device which then transmits toll and congestion capacity data through the network 214 or wireless GPS network 215 to call upon instruction routines and instruction sub-routines on the toll and congestion capacity forward market database server 271, virtual toll and congestion hub database server 223, network member database server 222, map routing servers 220, no arbitrage condition database server 280 and/or instructions in the memory of the cloud and local CPUs 219 which all interface together to make one system which may deliver toll and congestion capacity units to users 110 from and to a plurality of virtual toll and congestion hubs 410, 422 with a plurality of specifications at specific market prices which all interface together to make one system which may deliver toll and congestion capacity units to users 110 from and to a plurality of virtual hubs 1110, 1122 with a plurality of specifications at specific market prices.

FIG. 12 illustrates exemplary user interfaces 210 for participating, transacting and/or trading transformed toll and congestion capacity as a physical forward commodity or security between combinations of virtual toll and congestion hubs over various toll and congestion capacity modes. In some implementations and embodiments, user interface 210 includes the following elements, or a subset or superset thereof:

exemplary virtual hub combination 1211;

exemplary virtual hub origin/from location 1210 with users 1212 within the virtual hub location 1210;

exemplary specification summary of the market, level of service and time of delivery commencement 1227;

exemplary mode of train toll and congestion capacity type 1230;

exemplary transaction summary of the last trades quantity and price 1228;

exemplary virtual hub destination/to location 1222 and user who is being delivered on the toll and congestion capacity or freight toll and congestion capacity unit 1223;

exemplary bid/buy quantity title header 1215 for an exemplary virtual toll and congestion capacity or freight toll and congestion hub market;

exemplary bid/buy price title header 1216 for an exemplary virtual toll and congestion capacity or freight toll and congestion hub market;

exemplary offer/sell price title header 1219 for an exemplary virtual toll and congestion capacity or freight toll and congestion hub market;

exemplary offer/sell quantity title header 1226 for an exemplary virtual toll and congestion capacity for freight toll and congestion hub market;

exemplary bid/buy quantity 1214 for the best bid quantity from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight toll and congestion capacity virtual hub combination that has undergone a plurality of data transformations in the method 1211;

exemplary bid/buy quantity 1213 for the second-best bid quantity from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight capacity virtual hub combination that has undergone a plurality of data transformations in the method 1211;

exemplary bid/buy price 1218 for the best bid price from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight toll and congestion capacity virtual hub combination that has undergone a plurality of data transformations in the method 1211;

exemplary bid/buy price 1217 for the second-best bid price from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight toll and congestion capacity virtual hub combination that has undergone a plurality of data transformations in the method 1211;

exemplary offer/sell price 1221 for the best offer price from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight toll and congestion capacity virtual hub combination that has undergone a plurality of data transformations in the method 1211;

exemplary offer/sell price 1220 for the second-best offer price from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight toll and congestion capacity virtual hub combination that has undergone a plurality of data transformations in the method 1211;

exemplary offer/sell quantity 1225 for the best offer quantity from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight toll and congestion capacity virtual hub combination that has undergone a plurality of data transformations in the method 1211;

exemplary offer/sell quantity 1224 for the second-best offer quantity from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight toll and congestion capacity virtual toll and congestion hub combination that has undergone a plurality of data transformations in the method 1211;

exemplary safety dispatch “911” button 1229 to enact video and audio recording of the user 110 environment and dispatch of that information to authorities.

exemplary hamburger menu button 270 to move back to menu options and settings away from the participation, transaction, trading GUI 210 embodiment.

In some implementations and embodiments the user 110 may enter a transaction quantity and price for toll and congestion capacity or freight toll and congestion capacity units to participate, transact and/or trade by the GUI 210 detecting user 110 contact with a bid/buy price 1218 or offer/sell price 1221. The GUI 210 detects user 110 contact with any of the GUI 210 buttons which have been aforementioned. Upon user 110 contact with buttons or audio interface on the GUI 210, instructions are instantiated which allows the user 110 to change the specifications of the respective virtual hub combination 1211. A plurality of transformed prices and transformed markets may be presented based on a plurality of transformed contract specifications. In some implementations and embodiments, the best bid/buy price 1118 may be moving up in price or down in price depending on the market conditions at any given time. In some implementations and embodiments the last trade or last transacted price for a given specification is listed to help the user 110 understand how the market is moving so that the user 110 may submit a competitive offer/selling price 1221 or bid/buying price 1214. In some implementations and embodiments, users 110 may adjust settings of the GUI 210 to show more bid/buying prices 1217 or more offer/selling prices 1120. In some implementations and embodiments the matrix of market quantities and prices 1213, 1214, 1215, 1216, 1217, 1218, 1219, 1220, 1221, 1224, 1225, 1226 may be referred to as market depth in the GUI 210 embodiment. In some implementations and embodiments the number of users 110 may be displayed as user icons 1212 or 1223 for the amount of people logged in which desire to transact, trade or participate in a given virtual toll and congestion hub 1210 to virtual toll and congestion hub 1222 combination. In some implementations and embodiments, users 110 may select the toll and congestion capacity mode 1230 such that the user allows a market for only one form or mode of toll and congestion capacity as a commodity or security or the user 110 may allow the system to show multiple forms (multi-modal) of toll and congestion capacity between two virtual toll and congestion capacity hubs 1210, 1211, 1222. In some implementations and embodiments the GUI 210 may detect a user 110 selecting the 911 button 1229 which may activate voice and video recording functions on the mobile or stationary device 210 and transmit the data with a confirmation from the user 110 to the authorities to provide enhanced security while participating, transacting or trading transformed forward toll and congestion capacity or freight units as a commodity or security. In some implementations and embodiments the user may toggle between the GUI or CPU device 210 market view screen in FIG. 4 and other menu 270 options and settings by the user 110 selecting the hamburger button 270 and the GUI 210 detecting the user 110 input or contact or audio instructions. In some implementations and embodiments the GUI 210 may instantiate instructions in the memory of the mobile computing device 210 which then transmits toll and congestion capacity or freight toll and congestion capacity data through the network 214 or wireless GPS network 215 to call upon instruction routines and instruction sub-routines on the toll and congestion capacity forward market database server 271, virtual toll and congestion hub database server 223, network member database server 222, map routing servers 220, no arbitrage condition database server 220 and/or instructions in the memory of the cloud and local CPUs 219 which all interface together to make one system which may deliver toll and congestion capacity or freight capacity units to users 110 from and to a plurality of virtual hubs 1210, 1222 with a plurality of specifications at specific market prices.

FIG. 13 illustrates exemplary user interfaces 210 for participating, transacting and/or trading transformed toll and congestion capacity as a physical forward commodities or securities between combinations of virtual hubs over various toll and congestion capacity modes. In some implementations and embodiments, user interface 210 includes the following elements, or a subset or superset thereof:

exemplary virtual hub combination 1311;

exemplary virtual hub origin/from location 1310 with users 1312 within the virtual hub location 1310;

exemplary specification summary of the market, level of service and time of delivery commencement 1327;

exemplary mode of train toll and congestion capacity type 1330;

exemplary transaction summary of the last trades quantity and price 1328;

exemplary virtual hub destination/to location 1322 and user who is being delivered on the toll and congestion capacity or freight toll and congestion capacity unit 1323;

exemplary bid/buy quantity title header 1315 for an exemplary virtual toll and congestion capacity or freight hub market;

exemplary bid/buy price title header 1316 for an exemplary virtual toll and congestion capacity or freight toll and congestion hub market;

exemplary offer/sell price title header 1319 for an exemplary virtual toll and congestion capacity or freight toll and congestion hub market;

exemplary offer/sell quantity title header 1326 for an exemplary virtual toll and congestion capacity or freight hub market;

exemplary bid/buy quantity 1314 for the best bid quantity from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight toll and congestion capacity virtual hub combination that has undergone a plurality of data transformations in the method 1311;

exemplary bid/buy quantity 1313 for the second-best bid quantity from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight toll and congestion capacity virtual hub combination that has undergone a plurality of data transformations in the method 1311;

exemplary bid/buy price 1318 for the best bid price from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight toll and congestion capacity virtual hub combination that has undergone a plurality of data transformations in the method 1311;

exemplary bid/buy price 1317 for the second-best bid price from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight capacity virtual hub combination that has undergone a plurality of data transformations in the method 1311;

exemplary offer/sell price 1321 for the best offer price from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight toll and congestion capacity virtual hub combination that has undergone a plurality of data transformations in the method 1311;

exemplary offer/sell price 1320 for the second-best offer price from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight toll and congestion capacity virtual hub combination that has undergone a plurality of data transformations in the method 1311;

exemplary offer/sell quantity 1325 for the best offer quantity from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight toll and congestion capacity virtual hub combination that has undergone a plurality of data transformations in the method 1311;

exemplary offer/sell quantity 1324 for the second-best offer quantity from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight toll and congestion capacity virtual hub combination that has undergone a plurality of data transformations in the method 1311;

exemplary safety dispatch “911” button 1329 to enact video and audio recording of the user 110 environment and dispatch of that information to authorities.

exemplary hamburger menu button 270 to move back to menu options and settings away from the participation, transaction, trading GUI 210 embodiment.

In some implementations and embodiments the user 110 may enter a transaction quantity and price for toll and congestion capacity or freight capacity units to participate, transact and/or trade by the GUI 210 detecting user 110 contact or audio instructions with a bid/buy price 1318 or offer/sell price 1321. The GUI 210 detects user 110 contact with any of the GUI 210 buttons which have been aforementioned. Upon user 110 contact or audio interface with buttons or audio instructions on the GUI 210, instructions are instantiated which allows the user 110 to change the specifications of the respective virtual hub combination 1311. A plurality of prices and markets may be presented based on a plurality of transformed contract specifications. In some implementations and embodiments, the best bid/buy price 1318 may be moving up in price or down in price depending on the market conditions at any given time. In some implementations and embodiments the last trade or last transacted price for a given transformed specification is listed to help the user 110 understand how the market is moving so that the user 110 may submit a competitive offer/selling price 1321 or bid/buying price 1314. In some implementations and embodiments, users 110 may adjust settings of the GUI 210 to show more bid/buying prices 1317 or more offer/selling prices 1320. In some implementations and embodiments the matrix of market quantities and prices 1313, 1314, 1315, 1316, 1317, 1318, 1319, 1320, 1321, 1324, 1325, 1326 may be referred to as market depth in the GUI 210 embodiment. In some implementations and embodiments the number of users 110 may be displayed as user icons 1312 or 1323 for the amount of people logged in which desire to transact, trade or participate in a given virtual hub 1310 to virtual hub 1322 transformed combination. In some implementations and embodiments, users 110 may select the toll and congestion capacity mode 1330 such that the user allows a market for only one form of toll and congestion capacity as a commodity or the user 110 may allow the system to show multiple forms of transformed toll and congestion capacity or freight capacity or securities between two virtual toll and congestion capacity hubs 1310, 1311, 1322. In some implementations and embodiments, by way of example and not to limit by example to avoid doubt, transformed toll and congestion capacity units or transformed toll and congestion capacity unit securities may even be substitutable between modes if the other specifications meet the grade category of the transformed toll and congestion capacity unit specification or transformed toll and congestion capacity unit security. A user(s) 110 may have bought a transformed toll and congestion capacity unit with a specification and the delivery mechanism was a bus, however the bus user 110 bought back their transformed toll and congestion capacity unit or transformed toll and congestion capacity unit security and now the original purchaser may be matched with a car of another user 110 who will deliver the transformed toll and congestion capacity unit or transformed toll and congestion capacity unit security. In some implementations and embodiments, bus 816, train 1330, airplane 1130, car 430, or a plurality of other modes may be substitutable if the transformed toll and congestion capacity unit or transformed toll and congestion capacity unit security meets the delivery transformed specification grade. In some implementations and embodiments the GUI 210 may detect a user 110 selecting the 911 button 1329 which may activate voice and video recording functions on the mobile or stationary device 111 and transmit the data with a confirmation from the user 110 to the authorities to provide enhanced security while participating, transacting or trading forward toll and congestion capacity or freight toll and congestion capacity as a commodity. In some implementations and embodiments the user may toggle between the GUI 210 market view screen in FIG. 4 and other menu 270 options and settings by the user 110 selecting the hamburger button 270 and the GUI 210 detecting the user 110 input or contact. In some implementations and embodiments the GUI 210 may instantiate instructions in the memory of the mobile computing device 210 which then transmits toll and congestion capacity or freight capacity data through the network 214 or wireless GPS network 215 to call upon instruction routines and instruction sub-routines on the toll and congestion capacity forward market database server 220, virtual hub database server 223, network member database server 222, map routing servers 220, no arbitrage condition database server 220 and/or instructions in the memory of the cloud and local CPUs 210 which all interface together to make one system which may deliver toll and congestion capacity or freight capacity units to users 110 from and to a plurality of virtual hubs 1310, 1322 with a plurality of specifications at specific market prices.

FIG. 14 illustrates an exemplary user interface 210 for selecting menu options 1410 on a portable multifunction device in accordance with some embodiments. In some implementations and embodiments, user interface 210 includes the following elements, or a subset or superset thereof:

menu options 1410;

origin (From)/Destination (to) menu option 1411;

market menu option 1412;

timings and specs menu option 1413;

term and specs menu option 1414;

order time and type menu option 1415;

modes menu option 1416;

virtual hubs menu option 1417;

no arb settings menu option 1418;

orders and confirms menu option 1419;

pool message menu option 1420;

tax and accounting menu option 1421;

setting button 1440 to transmit the menu option;

hamburger button 270 to instruct the GUI 210 to take the user 110 to the menu screen.

In some implementations and embodiments, user interface 210 may be used by the user 110 to select a plurality of menu options 1410. In some implementations and embodiments, the user 110 may select the origin (from)/destination (to) menu option 1411 which may instruct the GUI 210 to go to an address input rendering 910 and/or FIG. 4. In some implementations and embodiments, the user 110, may contact the “market” menu option 1412 which may instruct the GUI 210 to render a market participation, transaction and/or trading screen such as 300, 400, 1100, 1200, or 1300. In some implementations and embodiments the user may toggle between the GUI 210 market view screen in FIG. 3 and other menu 270 options and settings by the user 110 selecting the hamburger button 270 and the GUI 210 detecting the user 110 input or contact. In some implementations and embodiments, the user 110, may contact the “timings and specs” menu option 1413 which may instruct the GUI 210 to render a timings and specs screen such as 500. In some implementations and embodiments, the user 110, may contact the “term and specs” menu option 1414 which may instruct the GUI 210 to render a term and specs screen such as 600. In some implementations and embodiments, the user 110, may contact the “order time and type” menu option 1415 which may instruct the GUI 210 to render an order time and type screen such as 700. In some implementations and embodiments, the user 110, may contact the “modes” menu option 1416 which may instruct the GUI 210 to render a mode screen such as 800. In some implementations and embodiments, the user 110, may contact the “Virtual Hubs” menu option 1417 which may instruct the GUI 210 to render a virtual toll and congestion hubs screen such as 900. In some implementations and embodiments, the user 110, may contact the “no arb settings” menu option 1418 which may instruct the GUI 210 to render a no arbitrage constraint screen such as 1000. In some implementations and embodiments, the user 110, may contact the “orders and confirms” menu option 1419 which may instruct the GUI 210 to render the market orders and transaction confirmations for the user 110. In some implementations and embodiments, the user 110, may contact the “pool message” menu option 1420 which may instruct the GUI 210 to message either the actual toll and congestion capacity unit processor 162 or the opposite seller user 110 or buyer user 110 depending on if the user 110 was an opposite buyer or seller of the toll and congestion capacity unit. In some implementations and embodiments, the user 110, may contact the “tax and accounting” menu option 1421 which may instruct the GUI 210 to render tax and accounting information for the respective user 110. In some implementations and embodiments the GUI 210 menu option selection 1410 may instantiate instructions in the memory of the mobile computing device 210 which then transmits toll and congestion capacity data through the network 214 or wireless GPS network 215 to call upon instruction routines and instruction sub-routines on the toll and congestion capacity forward market database server 271, virtual toll and congestion hub database server 223, network member database server 222, map routing server 220, no arbitrage condition database server 220 and/or instructions in the memory of the cloud and local CPUs 210 which all interface together to make one system which may deliver toll and congestion capacity or freight capacity units or securities to users 110 from and to a plurality of virtual hubs 410, 422 with a plurality of specifications at specific market prices.

FIG. 15 illustrates an exemplary network configuration 1500 in one exemplary implementation of participating, transacting and/or trading transformed toll and congestion capacity or freight toll and congestion capacity units or securities in accordance with some embodiments. In some implementations and embodiments, network configuration 1500 includes the following elements, or a subset or superset thereof:

wireless global positioning system (GPS) network 1510;

network/s 1511;

additional global positioning system (GPS) network 1512;

user member portable multifunction device 1513;

virtual hub database server 1514;

toll and congestion capacity forward market database server 1519;

additional user member portable multifunction device 1515;

network member database server 1520;

network member user 1516;

additional network member user 1517;

no arbitrage constraint database server 1521;

cloud and Local CPUs 1522;

toll and congestion capacity or freight toll and congestion capacity unit mode 1518.

In some implementations and embodiments, the software and/or instructions stored in memory of the cloud & local CPUs 1522 and portable multifunction devices 1513, 1515 may include additional instructions to instantiate specification requirements, participation, transactions, and/or trading on the toll and congestion capacity or freight toll and congestion capacity unit network 1511. In some implementations and embodiments, instructions may include standard database web services with the database as service provider (i.e. calling from the outside in, which lets the client GUI 210 or 1513 call each of the virtual hub database server 1514 and/or toll and congestion capacity forward market database server 1519 and/or network member database server 1520 and/or no arbitrage constraint database server 1521 and/or cloud & local CPUs 1522 through the wireless GPS network 1510 or network 1511. In some implementations and embodiments, each of the virtual hub database server 1514 and/or toll and congestion capacity forward market database server 1519 and/or network member database server 1520 and/or no arbitrage constraint database server 1521 and/or cloud & local CPUs 1522 may instruct the network to instantiate the database servers 1514, 1519, 1520, 1521, 1522 as service consumers (i.e. calling from the inside out, which lets a SQL query or application module in the database session consume an external web service. In some implementations and embodiments, users 1516 and/or 1517 may use portable multifunction devices 1513 and/or 1515 to access the toll and congestion capacity or freight capacity unit market GUI 210 so that the users 1516 and/or 1517 may participate, transact and/or trade toll and congestion capacity or freight toll and congestion capacity units. In some implementations and embodiments, the virtual hub database server 1514 stores map tile data in addition to user location data which is utilized by the GUI 210 to display or render location of virtual hubs and user 1516 proximity to those virtual hubs 200, 300, 400, 900, 1100, 1200, 1300. In some implementations and embodiments, the toll and congestion capacity forward market database server 1519 stores bid and offer data for respective quantities of users as well as transaction data and a plurality of market data for each virtual hub combination. In some implementations and embodiments, the network member database server 1520 stores user profile, user transaction, user trade, user settings, user specifications, user rating, user criminal history or background check data or facial recognition data or fingerprint recognition data or photo scan recognition data or ride history data, user track record, user bank data, user credit card data, user history data, user tax data and a plurality of other data. In some implementations and embodiments, the no arbitrage constraint database server 1521 stores data and algorithms to identify user 110 constraints 1000 and run algorithm calculations for users on specific constraints to check for compliance with constraints. In some implementations and embodiments, network servers and CPUs 1514, 1519, 1520, 1521, 1522, 1513, 1515 my interface through the network 1511 and/or wireless GPS networks 1510, 1512 such that toll and congestion capacity or freight capacity units may be participated in, transacted and/or traded efficiently in the context of a market for toll and congestion capacity units or securities. Included aforementioned data elements may be a subset or superset of data used for any specific calculation or transformation to participate, transact or trade toll and congestion capacity or freight capacity units or securities.

FIG. 16 illustrates a flowchart embodiment of steps a user may perform to participate, transact and/or trade transformed toll and congestion capacity units or securities between virtual hub combinations. In some implementations and embodiments a user at a mobile or portable multifunction device and/or fixed computing device with a touchscreen or a computing device without a touchscreen or augmented, audio interface computing device, mixed reality non-screen display may detect user login to the toll and congestion capacity unit network 1610. In some implementations and embodiments, the GUI of the toll and congestion capacity unit network may detect and receive origin location from user input or current GPS coordinate information and detect destination address from user input and transmission of data 1620. In some implementations and embodiments, the GUI and/or CPUs and/or databases may generate and apply one or more optimization techniques to form a virtual hub with other users that have similar toll and congestion capacity requests within a geographic boundary 1630. In some implementations and embodiments, the GUI and/or CPUs and or databases may generate instructions for a plurality of computing devices, network, virtual hub database server, network member database server and toll and congestion capacity forward market database server 271 to form a combination of virtual hubs and transformed contract specifications for delivery of toll and congestion capacity services or toll and congestion capacity or freight toll and congestion capacity between the virtual hubs in a format presented by a graphical user interface which allows users to enter forward physical prices to sell (offer) or bid (buy) toll and congestion capacity units or securities between virtual hub combinations 1640 in an open market auction format. In some implementations and embodiments, the GUI and/or CPUs and or databases may generate instructions to interface a plurality of networks, global positioning systems networks, servers, forward commodity market auctions, map routing servers, grouping instruction software for virtual hubs, navigation servers, transparent open access pricing systems, game servers, blockchain audit and safety systems, virtual hub servers and systems, no arbitrage constraint condition systems which form one system to implement a forward commodity toll and congestion capacity or freight capacity unit forward market system and method 1650.

FIG. 17 illustrates an exemplary embodiment of a user 110 most frequent toll and congestion capacity or freight unit routes 1710 in one exemplary implementation of participating, transacting and/or trading toll and congestion capacity or freight capacity units in accordance with some embodiments. In some implementations and embodiments, most frequent my routes include the following elements, or a subset or superset thereof:

Home to Work 1711 (may have subsets of transformed data);

Work to Home 1712 (may have subsets of transformed data);

Home to School 1713 (may have subsets of transformed data);

School to Home 1714 (may have subsets of transformed data);

Work to Gym 1715 (may have subsets of transformed data);

Home to Gym 1716 (may have subsets of transformed data);

Gym to Home 1717 (may have subsets of transformed data);

Home to Grocery 1718 (may have subsets of transformed data);

Home to Downtown 1719 (may have subsets of transformed data);

Downtown to Home 1720 (may have subsets of transformed data);

Freight Center to X where X is a delivery route or multi virtual hub combination 1721 (may have subsets of transformed data);

+Add Route 1722 (may have subsets of transformed data);

Edit 1723 (may have subsets of transformed data);

Setting button 1740 to transmit the My Routes data;

Hamburger button 270 to instruct the GUI 210 to take the user 110 to the menu screen.

In some implementations and embodiments, the GUI 210 may be used to select, store and/or edit user 110 frequent or preferred routes (“MY ROUTES”) 1710 for more efficient access to toll and congestion capacity unit markets over various modes and specifications of toll and congestion capacity.

In some implementations and embodiments, the user 110 may select, store and/or edit address and specification data for “Home to Work” 1711 and/or “Work to Home” 1712 and/or “Home to School” 1713 and/or “School to Home” 1714 and/or “Work to Gym” 1715 and/or “Home to Gym” 1716 and/or “Gym to Home” 1717 and/or “Home to Grocery” 1718 and/or “Home to Downtown” 1719 and/or “Downtown to Home” 1720 and/or “Freight Center to X” 1721 and/or “+Add Route” 1722. In some implementations and embodiments, the My Routes 1710 module may include any route a user 110 may request on any toll and congestion capacity or freight capacity unit mode and/or specification. In some implementations and embodiments the user may toggle between the GUI 210 market view screen in FIG. 3 and other menu 270 options and settings by the user 110 selecting the hamburger button 270 and the GUI 210 detecting the user 110 input or contact. In some implementations and embodiments, the user 110 is notified via SMS text, in application, email or a plurality of other well-known communication methods when market activity occurs on a given route or virtual hub combination. In other words, the “my routes” 1710 feature not only allows for one touch access to a saved route, but also performs notification features between users. Lastly, In some implementations and embodiments, the EDIT 1750 button allows a user 110 to modify a plurality of notification settings such as email, SMS text, in application, voice, messaging or other notification methods.

FIG. 18 illustrates an exemplary network topology configuration 1800 in one exemplary implementation of participating, transacting and/or trading transformed toll and congestion capacity or freight toll and congestion capacity units or securities in accordance with some embodiments. In some implementations and embodiments, network configuration 1800 includes the following elements, or a subset or superset thereof:

large virtual toll and congestion hub nodes such as 1801, 1802, 1803, 1804, 1805;

medium virtual toll and congestion hub nodes such as 1810, 1811, 1809, 1808, 1807, 1806;

small virtual toll and congestion hub nodes such as 1812, 1813, 1814, 1815, 1816, 1816, 1817, 1818, 1819, 1820, 1821;

In some implementations and embodiments, the overall network node topology 1800 is comprised of large virtual hub nodes 1801, 1802, 1803, 1804, 1805 and medium virtual hub nodes 1810, 1811, 1809, 1808, 1807, 1806 and small virtual hub nodes 1812, 1813, 1814, 1815, 1816, 1816, 1817, 1818, 1819, 1820, 1821, or a subset or superset thereof. In some implementations and embodiments a user may input a starting point of 1815 and an ending point of 1818 which represent specific geographic virtual hub locations in a city, multiple cities or even countries or multiple countries. In some implementations and embodiments, forward toll and congestion capacity market auctions may occur directly between two exemplary points such as 1815 and 1818 or the method and system may combine a series of smaller auctions to comprise a larger auction between two endpoints on the system. In some implementations and embodiments, a series of smaller auctions may be combined between 1815 and 1811 as well as 1811 and 1802 as well as 1802 and 1805 as well as 1805 and 1808 as well as 1808 and 1818 which would be added together to make a combined virtual hub auction. A combined series of smaller auctions may be constrained by instructions which form auctions based on cheapest toll and congestion capacity or freight route 1011, single mode transport or freight auctions 1012, multi-mode toll and congestion transport or toll and congestion freight 1013, fastest transport or freight constraints 1014, most scenic auctions 1015, highest rating auctions 1016, most available or liquid auctions 1017, highest volume auctions 1018, most frequent auctions 1019, service level auctions 1020, security and safety level auctions 1021, group restricted auctions by sex, email, organization, gender or other 1022. In some implementations and embodiments, the constraints allow for many types of auctions which are unique and novel for transformed toll and congestion capacity and freight capacity units or securities in a forward toll and congestion capacity and freight market. In some implementations and embodiments, the user 110 may specify instructions that set forward market auction constraints based on one or a plurality of constraints. In some implementations and embodiments, the constrained auctions may have fungible units which allow many participants to transact in the auctions. In some implementations and embodiments, the disclosed creation of a forward market of toll and congestion capacity units between virtual toll and congestion hubs 1801 and 1804 or other combinations along map routes has the attributes of a fungible forward contract which allows for one toll and congestion capacity unit to be substitutable for another toll and congestion capacity unit because the unit has been transformed and defined as a commodity contract. In other words, if user A bought a toll and congestion capacity unit from user B between 1801 virtual hub and 1804 virtual hub, but then user A was not able to perform the obligation to purchase the toll and congestion capacity unit between 1801 virtual hub and 1804 virtual hub from user B, user A could resell the toll and congestion capacity unit contract between virtual hub 1801 and virtual hub 1804 to a third party user C on the forward toll and congestion capacity unit auction market between virtual hub 1804 and virtual hub 1801 to retrieve the financial payment made for their original purchase from user B and then user C would replace user A and be matched with user B for the toll and congestion capacity unit transformation between virtual hub 1804 and virtual hub 1801. No other prior art system or method performs the aforementioned data transformation combination. In some implementations and embodiments, the toll and congestion capacity or freight unit auction substitutability dynamic creates a unique and novel invention that does not exist in the world today. In some implementations and embodiments, user 110 input 210 instructions use constrained optimization to form one toll and congestion auction between two points or a series of multiple auctions that form one larger auction.

In some implementations and embodiments, the forward toll and congestion capacity and freight unit auctions subject to various constraints may be presented as a linear programming cost minimization problem in the exemplary case where the user 110 selects the cheapest route 1011 constraint. In such exemplary case, the series of auctions may be combined that utilize the lowest cost path between the start point 1815 and the ending point 1818. In such exemplary case, the linear programming cost minimization function may select the following path of 1815 to 1811 to 1802 to 1804 to 1805 to 1808 to 1818 if that combination is the lowest cost auction path. In another such exemplary case, the user 110 may select instructions for the auction to minimize both cost and shortest route. In such exemplary case the linear programming function may minimize cost subject to a constraint that time is the shortest along the path and the resulting auction may combine a different and unique series of auctions between the starting point of 1815 and ending point 1818. Accordingly, the path may be optimized to minimize cost subject to the shortest path that yields a path of 1815 to 1811 to 1802 to 1805 to 1808 to 1818. The plurality of combinations of linear programming sequences of auctions for toll and congestion capacity or freight units between two points may consider an infinite set of combinations and permutations.

In some implementations and embodiments, the forward transformed toll and congestion capacity and freight unit or transformed toll and congestion capacity security unit auctions may be held side by side between two competing routes 4200. By way of example but not limiting by example a user may input instructions for the method and system to route between 1801 virtual toll and congestion hub and 1805 virtual toll and congestion hub. One route may be directly between 1801 virtual toll and congestion hub and 1805 virtual toll and congestion hub. Another route may be between virtual toll and congestion hub 1801 and virtual toll and congestion hub 1805 by way of virtual toll and congestion hub 1802. The time between the toll and congestion routes may vary due to traffic, construction, road conditions, accidents or a plurality of other exogenous factors, however, the data transformation of the disclosed method allows for two auctions to form side by side. Side by side toll and congestion auctions may be displayed on a market based user interface 1300 or as a software layer of instructions over a navigation system 4200. The first toll and congestion capacity unit auction may be between virtual toll and congestion hub 1805 and virtual toll and congestion hub 1801 directly as one auction. A second auction may be by combining two smaller auctions between virtual toll and congestion hub 1805 and virtual toll and congestion hub 1802 with the auction between 1802 virtual toll and congestion hub and 1801 virtual toll and congestion hub which could be expressed independently or as a combined auction. The plurality of route auctions for the toll and congestion capacity unit (auction one directly between 1801 virtual hub and 1805 virtual hub) (auction two between 1801 virtual toll and congestion hub and 1805 virtual toll and congestion hub by way of 1802 virtual toll and congestion hub) may allow for the user to have transparent price auction information for the value of various proposed routes which have different price values.

FIG. 19 illustrates an exemplary delivery and pick up geofence status configuration 1900 in one exemplary implementation of participating, transacting and/or trading transformed toll and congestion capacity or freight toll and congestion capacity units or securities in accordance with some embodiments. In some implementations and embodiments, the delivery and pick up status configuration 1900 includes the following elements, or a subset or superset thereof:

computing device unit GUI 210 to display method of multi layered network node topology for forward market of toll and congestion capacity and freight units.

hamburger menu toggle 270 to move between different application configurations;

virtual toll and congestion hub 1 pickup address and virtual toll and congestion hub 2 destination address at a contract specification with regards to quality, day, date and time 1910;

trip status for PickUp of toll and congestion capacity or freight toll and congestion unit 1920;

Checkln passenger or freight status for toll and congestion capacity unit 1930;

messaging texts and instructions between users to make pick up and delivery of toll and congestion capacity or freight toll and congestion capacity units 1940;

call between users with number masking for privacy security 1950;

GPS map location of user 110 who is a rider or if freight toll and congestion cargo location 1960;

GPS map location of user 110 who is a driver or if freight, cargo carrier toll and congestion unit location 1970;

GPS map of toll and congestion capacity or freight unit delivery and pickup 1980;

Texting message window for freight or toll and congestion capacity unit communication between users 1991;

PickUp address data window during PickUp status 1992;

Security button to report security issues to 911 and system database 1990;

In some implementations and embodiments, the GUI 210 transmits delivery instructions to the users 110 to help the user have a rendering or map of their GPS location 1960 relative to the selling user 1970 of freight or toll and congestion capacity units. In some implementations and embodiments, the GUI 210 displays the trips status such as PickUp 1920 status, the trip status may include subsets or supersets of various status conditions such as PickUp, start, leaving, on-going, in-progress, arriving, arrived or a plurality of other trip status conditions. In some implementations and embodiments, the trip view of the GUI 210 may include a Checkln 1930 button to confirm a passenger or freight transformed toll and congestion capacity unit has been moved into the transformed toll and congestion capacity unit object which could be a car, airplane, autonomous vehicle, bike, boat, ship, bus, drone, limo, motorcycle, moped, shuttle, spaceship, subway, taxi, train, cargo, combination of transformed modes or other type of toll and congestion capacity mode. In some implementations and embodiments, the user 110 may transmit a message using the message 1940 button which may transmit audio, visual or text messages between users 110, 1970, 1960. In some implementations and embodiments, the users 110, 1960, 1970 may call each other using the call 1950 button to communicate pickup or delivery instructions. In some implementations and embodiments, a user 110, 1960, 1970 may message another user 110, 1960, 1970 to communicate using the PickUp Message window 1991 which may utilize visual, audio or text communication modes as well as log a message history between users. In some implementations and embodiments the users 110, 1960, 1970 may toggle to other modes of the application using the menu hamburger button 270. In some implementations and embodiments the GPS display of a map with the relative position of a toll and congestion capacity or freight unit seller 1970 and a toll and congestion capacity or freight unit buyer 1960 are displayed to help users 110 understand each others relative position and location on a map 1980. In some implementations and embodiments the GPS location of the toll and congestion capacity and freight toll and congestion unit seller 1970 and toll and congestion capacity or freight unit buyer 1960 are tracked in real time with location updates on the map 1980.

FIG. 20 illustrates an exemplary Checkln configuration 2000 in one exemplary implementation of participating, transacting and/or trading toll and congestion capacity or freight toll and congestion capacity units in accordance with some embodiments. In some implementations and embodiments, the Checkln 2050 for a buyer or seller of a toll and congestion capacity or freight unit includes the following elements, or a subset or superset thereof:

computing device unit GUI 210 to display method of multi layered network node topology for forward market of toll and congestion capacity and freight units with security Checkln.

hamburger menu toggle 270 to move between different application configurations;

driver or seller of toll and congestion capacity or freight toll and congestion capacity unit scan check for finger print, face scan or picture photo scan to verify identity of user 2051;

passenger or freight and toll and congestion capacity unit buyer unit scan check for finger print, face scan or picture photo scan to verify identity of user 2052;

transport verification confirmation window to confirm identities of users in the system at the application system level 2053;

buyer and seller of toll and congestion capacity or freight toll and congestion capacity unit facial recognition confirmation 2010;

buyer and seller of toll and congestion capacity or freight toll and congestion capacity unit finger print recognition confirmation 2020;

buyer and seller of toll and congestion capacity or freight unit photo recognition confirmation 2030;

In some implementations and embodiments, the GUI 210 of a computing device transmits and confirms the identity of users against identity records in the Network Member Database Server 222 which also confirms security checks for criminal records or other activity that would suspend a user from the platform environment. In some implementations and embodiments, the driver verification window 2051 may fail an identity verification due to a user not being the registered user 2010 on the Network Member Database Server 222. In some implementations and embodiments, the passenger or freight verification window 2052 may fail an identity verification due to a user 2010 not being the registered user on the network member database server 222. In some implementations and embodiments, the transport verification window 2053 may instruct the user 2010 to proceed to destination if verification is successful. In some implementations and embodiments, the transport verification window 2053 may instruct the user not to proceed to the destination if the verification is not successful. The identity verification system is unique and novel and dependent on a novel and unique auction forward market for transformed toll and congestion capacity unit or freight unit or securities over multiple nodes or virtual hubs topologies.

FIG. 21 illustrates an exemplary delivery and pick up status configuration 2100 once a toll and congestion capacity or freight toll and congestion unit delivery has started in one exemplary implementation of participating, transacting and/or trading toll and congestion capacity or freight capacity units in accordance with some embodiments. In some implementations and embodiments, the delivery and pick up status configuration 2100 includes the following elements, or a subset or superset thereof:

computing device unit GUI 210 to display method of multi layered network node topology for forward market of toll and congestion capacity and freight units.

hamburger menu toggle 270 to move between different application configurations;

virtual toll and congestion hub 1 pickup address and virtual toll and congestion hub 2 destination address at a transformed contract specification with regards to quality, day, date and time 2103 of delivery of a toll and congestion capacity or freight unit;

trip status of started of toll and congestion capacity or freight toll and congestion unit or security 2102;

finish trip passenger or freight status for toll and congestion capacity unit 2104 once a toll and congestion capacity or freight toll and congestion capacity unit has been delivered;

messaging texts and instructions between users to make pick-up, on-going route status and delivery complete of toll and congestion capacity or freight capacity units 2105;

call between system users with number masking for privacy security 2106;

GPS map location of user 2109 who is a rider or if freight, cargo location 2109;

GPS map location of user 2108 who is a driver or if freight, cargo carrier unit location 2108;

GPS map of toll and congestion capacity or freight unit delivery and pickup 2110;

Texting message window for freight or toll and congestion capacity unit communication between users 2112;

Starting point of virtual hub for forward toll and congestion capacity or freight units 2107;

Security button to report security issues to 911 and system database 2111;

Drop off address for delivery of passenger or freight for toll and congestion capacity or freight toll and congestion unit 2111.

In some implementations and embodiments, the GUI 210 transmits delivery instructions to the users 110 to help the user have a rendering or map of their GPS location 2109 relative to the selling user 2108 of transformed freight or toll and congestion capacity units or securities. In some implementations and embodiments, the GUI 210 displays the trips status such as Started 2102 status, the trip status may include subsets or supersets of various status conditions such as PickUp, Started, leaving, on-going, in-progress, arriving, arrived or a plurality of other trip status conditions. In some implementations and embodiments, the trip view of the GUI 210 may include a Finish 2104 button to confirm a passenger or freight toll and congestion capacity unit has been delivered or completed by the toll and congestion capacity unit object which could be a car, airplane, autonomous vehicle, bike, boat, ship, bus, drone, limo, motorcycle, moped, shuttle, spaceship, subway, taxi, train, eScooter, eBike, cargo or other types of toll and congestion capacity modes. In some implementations and embodiments, the user 110 may transmit a message using the message 2105 button which may transmit audio, visual or text messages between users 110, 2109, 2108. In some implementations and embodiments, the users 110, 2109, 2109 may call each other using the call 2106 button to communicate pickup or delivery instructions or other necessary communication. In some implementations and embodiments, a user 110, 2109, 2108 may message another user 110, 2109, 2108 to communicate using the Message-User window 2112 which may utilize visual, audio or text communication modes as well as log a message history between users. In some implementations and embodiments the users 110, 2109, 2108 may toggle to other modes of the application using the menu hamburger button 270. In some implementations and embodiments the GPS display of a map with the relative position of a transformed toll and congestion capacity or freight unit or security seller 2108 and a transformed toll and congestion capacity or freight unit or security buyer 2109 are displayed to help users 110 understand each others relative position and location on a map 2110. In some implementations and embodiments the GPS location of the toll and congestion capacity and freight toll and congestion capacity unit seller 2108 and toll and congestion capacity or freight toll and congestion capacity unit buyer 2109 are tracked in real time with location updates on the map 2110.

FIG. 22 illustrates an exemplary delivery and pick up status configuration 2200 once a toll and congestion capacity or freight unit delivery is ongoing in one exemplary implementation of participating, transacting and/or trading transformed toll and congestion capacity or freight capacity units or securities in accordance with some embodiments. In some implementations and embodiments, the delivery and pick up status configuration 2200 includes the following elements, or a subset or superset thereof:

computing device unit GUI 210 to display method of multi layered network node topology for forward market of toll and congestion capacity and freight units.

hamburger menu toggle 270 to move between different application configurations;

virtual toll and congestion hub 1 pickup address and virtual toll and congestion hub 2 destination address at a contract specification with regards to quality, day, date and time 2201 of delivery of a toll and congestion capacity or freight toll and congestion capacity unit;

trip status of ongoing for toll and congestion capacity or freight unit 2202;

finish trip passenger or freight status button for toll and congestion capacity unit 2203 once a toll and congestion capacity or freight toll and congestion capacity unit has been delivered;

messaging texts and instructions between users to make pick-up, on-going route status and delivery complete of toll and congestion capacity or freight toll and congestion capacity units 2204;

call between system users with number masking for privacy security 2205;

GPS map location of user 2209 who is a rider or if freight, cargo location 2209;

GPS map location of user 2208 who is a driver or if freight, cargo carrier unit location 2207;

GPS map of toll and congestion capacity or freight unit delivery and pickup 2206;

texting message window for freight or toll and congestion capacity unit communication between users 2211;

starting point of virtual hub for forward toll and congestion capacity or freight toll and congestion capacity units 2206;

security button to report and record security issues to 911 and system database 2210;

drop off address for delivery of passenger or freight for toll and congestion capacity or freight toll and congestion capacity unit 2212.

In some implementations and embodiments, the GUI 210 transmits delivery instructions to the users 110 to help the user 110 have a rendering or map of their GPS location 2207 relative to the selling user 2208 of freight or toll and congestion capacity units. In some implementations and embodiments, the GUI 210 displays the trips status such as On-Going 2202 status, the trip status may include subsets or supersets of various status conditions such as PickUp, Started, leaving, on-going, in-progress, arriving, arrived or a plurality of other trip status conditions. In some implementations and embodiments, the trip view of the GUI 210 may include a Finish 2203 button to confirm a passenger or freight toll and congestion capacity unit or security has been delivered or completed by the toll and congestion capacity unit object which could be a car, airplane, autonomous vehicle, bike, boat, ship, bus, drone, limo, motorcycle, moped, shuttle, spaceship, subway, taxi, train, cargo or other types of toll and congestion capacity modes. In some implementations and embodiments, the user 110 may transmit a message using the message 2204 button which may transmit audio, visual or text messages between users 110, 2207, 2208. In some implementations and embodiments, the users 110, 2207, 2208 may call each other using the call 2205 button to communicate pickup or delivery instructions or other necessary communication. In some implementations and embodiments, a user 110, 2207, 2208 may message another user 110, 2207, 2208 to communicate using the Message-User window 2211 which may utilize visual, audio or text communication modes as well as log a message history between users 110, 2207, 2208. In some implementations and embodiments the users 110, 2207, 2208 may toggle to other modes of the application using the menu hamburger button 270. In some implementations and embodiments the GPS display of a map with the relative position of a toll and congestion capacity or freight unit seller 2208 and a toll and congestion capacity or freight unit buyer 2207 are displayed to help users 110 understand each others relative position and location on a map 2209. In some implementations and embodiments the GPS location of the toll and congestion capacity and freight unit seller 2208 and toll and congestion capacity or freight unit buyer 2207 are tracked in real time with location updates on the map 2209. In some implementations and embodiments, the GUI 210 may display the Drop Off Address 2212 of the toll and congestion capacity or freight unit. In some implementations and embodiments a user 110, 2207, 2208 may use a 911 button 2210 to submit a recording to the system servers and to authorities who are connected to the system if anything has occurred that may compromise the security of any user or toll and congestion capacity unit.

FIG. 23 illustrates an exemplary delivery and pick up status configuration 2300 once a toll and congestion capacity or freight unit delivery has arrived in one exemplary implementation of participating, transacting and/or trading toll and congestion capacity or freight capacity units in accordance with some embodiments. In some implementations and embodiments, the delivery and pick up status configuration 2300 includes the following elements, or a subset or superset thereof:

Computing device unit GUI 210 to display method of multi layered network node topology for forward market of toll and congestion capacity and freight toll and congestion capacity units.

hamburger menu toggle 270 to move between different application configurations;

virtual hub 1 pickup address and virtual hub 2 destination address at a contract specification with regards to quality, day, date and time 2301 of delivery of a toll and congestion capacity or freight toll and congestion capacity unit;

trip status of arrived for toll and congestion capacity or freight toll and congestion capacity unit 2302;

finish trip passenger or freight status button for toll and congestion capacity unit 2303 once a toll and congestion capacity or freight toll and congestion capacity unit has been delivered;

messaging texts and instructions between users to make pick-up, on-going route status and delivery complete of toll and congestion capacity or freight capacity units 2304;

call between system users with number masking for privacy security 2305;

GPS map location of user 2307 who is a rider or if freight, cargo location 2307;

GPS map location of user 2307 who is a driver or if freight, cargo carrier unit location 2307;

GPS map of toll and congestion capacity or freight toll and congestion capacity unit delivery and pickup 2308;

texting message window for freight or toll and congestion capacity unit communication between users 2311;

starting point of virtual hub for forward transformed toll and congestion capacity or freight units or securities 2306;

ending point of virtual hub for forward transformed toll and congestion capacity units or freight units or securities 2307;

security button to report and record security issues to 911 and system database 2309;

drop off address for delivery of passenger or freight for toll and congestion capacity or freight unit 2312;

In some implementations and embodiments, the GUI 210 transmits delivery instructions to the users 110 to help the user 110 have a rendering or map of their GPS location 2307 relative to the selling user 2307 of freight or toll and congestion capacity units. In some implementations and embodiments, the GUI 210 displays the trips status such as Arrived 2302 status, the trip status may include subsets or supersets of various status conditions such as PickUp, Started, leaving, on-going, in-progress, arriving, arrived or a plurality of other trip status conditions. In some implementations and embodiments, the trip view of the GUI 210 may include a Finish 2303 button to confirm a passenger or freight toll and congestion capacity unit has been delivered or completed by the toll and congestion capacity unit object which could be a car, airplane, autonomous vehicle, bike, boat, ship, bus, drone, limo, motorcycle, moped, shuttle, spaceship, subway, taxi, train, cargo or other types of toll and congestion capacity modes. In some implementations and embodiments, the user 110 may transmit a message using the message 2304 button which may transmit audio, visual or text messages between users 110, 2307. In some implementations and embodiments, the users 110, 2307 may call each other using the call 2305 button to communicate pickup or delivery instructions or other necessary communication. In some implementations and embodiments, a user 110, 2307 may message another user 110, 2307 to communicate using the Message-User window 2311 which may utilize visual, audio or text communication modes as well as log a message history between users 110, 2307. In some implementations and embodiments the users 110, 2307 may toggle to other modes of the application using the menu hamburger button 270. In some implementations and embodiments the GPS display of a map with the relative position of a toll and congestion capacity or freight unit seller 2307 and a toll and congestion capacity or freight toll and congestion capacity unit buyer 2307 are displayed to help users 110 understand each others relative position and location on a map 2308. In some implementations and embodiments the GPS location of the toll and congestion capacity and freight unit seller 2307 and transformed toll and congestion capacity or freight unit or security buyer 2307 are tracked in real time with location updates on the map 2308. In some implementations and embodiments, the GUI 210 may display the Drop Off Address 2312 of the transformed toll and congestion capacity or freight unit or security. In some implementations and embodiments a user 110, 2307 may use a 911 button 2309 to submit a recording to the system servers and to authorities who are connected to the system if anything has occurred that may compromise the security of any user or toll and congestion capacity unit.

FIG. 24 illustrates an exemplary delivery and pick up configuration 2400 for a toll and congestion capacity or freight toll and congestion capacity unit multi layered network node topology in one exemplary implementation of participating, transacting and/or trading toll and congestion capacity or freight toll and congestion capacity units in accordance with some embodiments. In some implementations and embodiments, the multi layered network node topology of participating, transacting and/or trading toll and congestion capacity or freight capacity configuration 2400 includes the following elements, or a subset or superset thereof:

computing device unit GUI 210 to display method of multi layered network node topology for forward market of toll and congestion capacity and freight toll and congestion capacity units;

hamburger menu toggle 270 to move between different application configurations;

from node starting point 2401 of a multi layered network node topology for forward market of toll and congestion capacity and freight toll and congestion capacity units;

to or destination node ending point 2402 of a multi layered network node topology for forward market of toll and congestion capacity and freight toll and congestion capacity units;

date module 2403 in GUI 210 of an auction for a multi layered network node topology for forward market of transformed toll and congestion capacity and freight toll and congestion capacity units or securities;

time module 2404 in GUI 210 of pickup and delivery of an auction for a multi layered network node topology for forward market of toll and congestion capacity and freight toll and congestion capacity units;

Go button 2405 to form an auction for a multi layered network node topology for forward market of transformed toll and congestion capacity and freight toll and congestion capacity units or securities;

My Routes button 2406 to quickly obtain common From 2401 or To 2402 points in an auction for a multi layered network node topology for forward market of transformed toll and congestion capacity and freight toll and congestion capacity units for a user on the system;

Multi-Hub network 2407, 2408, 2409, 2410 which may form a single dual node auction 2407 to 2408 or 2407 to 2410 or any possible node combination or a multi-node auction series for a multi layered network node topology for forward market of toll and congestion capacity and freight toll and congestion capacity units for a user on the system.

In some implementations and embodiments, the GUI 210 transmits a From node 2401 and To node 2402 with instructions to the users 110 with a specific date 2403 and time 2404 of a multi layered network node topology for forward market of transformed toll and congestion capacity and freight units for a user on the system to perform an auction by pressing the Go button 2405. The system may use a plurality of constraints such as but not limited by cheapest route 1011, single mode of toll and congestion capacity 1012, multi method mode of toll and congestion capacity 1013, fastest route 1014, most scenic route 1015, highest rated route or highest rated driver 1016, most available route 1017, highest volume route 1018, most frequent route 1019, service level route 1020, security and safety of route 1021, group restricted email or group criteria 1022 to use any two node points 2407, 2408, 2409, 2410 or any combination of points 2407, 2408, 2409, 2410. In some implementations and embodiments the system may use no constraint, one constraint or a plurality of constraints to allow the user 110 to participate, transact or trade in a multi layered network node topology for forward market of toll and congestion capacity and freight units in an auction. In some implementations and embodiments the auction for forward market transformed toll and congestion capacity or freight units or securities may be comprised of an auction between only two points or a plurality of points subject to a plurality of constraints. In some implementations and embodiments the from or starting point or starting virtual hub may be 2407, but the system selects an auction between 2408 and 2409 rather than starting at 2407 because one or more constraints were selected to frame the auction for forward market toll and congestion capacity or freight units. In some implementations and embodiments, an auction may be comprised of multiple modes of toll and congestion capacity comprising a car ride toll and congestion capacity or freight unit auction between 2407 and 2408 points, followed by an airplane toll and congestion capacity or freight unit auction between 2408 and 2409, followed by a ship auction between 2410 and 2409 for toll and congestion capacity or freight units. In some implementations and embodiments the various plurality of auctions may be displayed as one auction or a series of auctions. In some implementations and embodiments, auctions for a multi layered network node topology for a forward market of toll and congestion capacity and freight units may consist of any subset or superset of the aforementioned possibilities including any constraints 1000 or any plurality of modes 800.

FIG. 25 illustrates an exemplary setting configuration 2500 for a toll and congestion capacity or freight toll and congestion capacity unit multi layered network node topology in one exemplary implementation of participating, transacting and/or trading toll and congestion capacity or freight capacity units in accordance with some embodiments. In some implementations and embodiments, the multi layered network node topology of participating, transacting and/or trading toll and congestion capacity or freight capacity configuration 2500 includes the following setting elements, or a subset or superset thereof:

computing device unit GUI 210 to display method of multi layered network node topology for forward market of transformed toll and congestion capacity and freight toll and congestion capacity units or securities.

hamburger menu toggle 270 to move between different application configurations;

open markets setting toggle 2510 which allows a user to see all market participants of a given auction on a multi layered network node topology for a forward market of transformed toll and congestion capacity and freight toll and congestion capacity units or securities;

restricted markets setting By Organization 2520, By Sex 2530, By Rating 2540, By Security 2550 or by any other restriction the user 110 defines which limit the auction participants for the user;

privacy settings which restrict push notifications 2560, location information 2570; Sync with contacts 2580, or other privacy settings;

In some implementations and embodiments, a user 110 may select open markets 2510 which show every participant in a given auction for a multi layered network node topology for a forward market of toll and congestion capacity and freight units. In some implementations and embodiments, participants or users 110 may select to restrict the market view of the GUI such as 400 by organization email 2520 or by sex 2530 or by rating of driver 2540 or rating of user 2540 or by security 2550 or by a plurality of other restrictions but not limited to those restrictions. In some implementations and embodiments, users 110 may change privacy settings which restrict push notifications 2560, location settings 2570, Sync with Contacts settings 2580 or a plurality of other settings. In some implementations and embodiments, the toggle switches 2510, 2520, 2530, 2540, 2550, 2560, 2570, 2580 may be set to off or on depending on if they hold a right or left toggle switch position. The restricted market settings 2520, 2530, 2540, 2550 may be a subset or superset of the aforementioned in the formation of an open market auction for a multi layered network node topology for a forward market of toll and congestion capacity and freight toll and congestion capacity units.

FIG. 26 illustrates an exemplary setting for a package or cargo scan configuration 2600 for a transformed toll and congestion capacity or freight toll and congestion capacity unit multi layered network node topology in one exemplary implementation of participating, transacting and/or trading toll and congestion capacity or freight capacity units in accordance with some embodiments. In some implementations and embodiments, the multi layered network node topology of participating, transacting and/or trading toll and congestion capacity or freight capacity configuration 2600 includes the following setting for a package or cargo scan elements, or a subset or superset thereof:

computing device unit GUI 210 to display method of multi layered network node topology for forward market of transformed toll and congestion capacity and freight units.

hamburger menu toggle 270 to move between different application configurations;

package or Cargo Scan module 2610 to document the status and position of transformed forward market freight or toll and congestion capacity units or security;

package or cargo Inbound or received module 2692 to scan a picture, universal product code barcode, QR code, or other transformed toll and congestion capacity or freight toll and congestion capacity unit identifier or security;

package or cargo Inbound scan toggle switch 2620 to scan a picture, universal product code barcode, QR code, or other transformed toll and congestion capacity or freight toll and congestion capacity unit identifier or security;

Cargo unit Inbound scan toggle switch 2640 to scan a picture, universal product code barcode, QR code, or other transformed toll and congestion capacity or freight toll and congestion capacity unit identifier or security;

Trailer unit Inbound scan toggle switch 2650 to scan a picture, universal product code barcode, QR code, or other transformed toll and congestion capacity or freight toll and congestion capacity unit identifier or security;

Container unit Inbound scan toggle switch 2660 to scan a picture, universal product code barcode, QR code, or other transformed toll and congestion capacity or freight toll and congestion capacity unit identifier or security;

Package or Cargo Outbound or delivered module 2693 to scan a picture, universal product code barcode, QR code, or other transformed toll and congestion capacity or freight toll and congestion capacity unit or security identifier or security;

Package or Cargo Outbound or delivered scan toggle 2670 to scan a picture, universal product code barcode, QR code, or other transformed toll and congestion capacity or freight toll and congestion capacity unit identifier or security;

Cargo Outbound or delivered scan toggle 2680 to scan a picture, universal product code barcode, QR code, or other transformed toll and congestion capacity or freight toll and congestion capacity unit identifier;

Trailer Outbound or delivered scan toggle 2690 to scan a picture, universal product code barcode, QR code, or other transformed toll and congestion capacity or freight unit identifier;

Container Unit Outbound or delivered scan toggle 2691 to scan a picture, universal product code barcode, QR code, or other transformed toll and congestion capacity or freight unit identifier;

In some implementations and embodiments, a user 110 may select the package or cargo unit scan module 2610 to scan or take a picture of a package or cargo identification code such as a QR code, Uniform Product code or other identifying package or cargo characteristic. In some implementations and embodiments, the user 110 may select the inbound Scan/Picture Package toggle 2620 which captures the identification characteristic which may include QR Codes, Uniform Product Codes, Serial Numbers or other cargo identification characteristics of a package or cargo toll and congestion capacity or freight unit. In some implementations and embodiments, inbound cargo may include a larger unit structure than a package such as a crate or large movable unit with identification characteristics which may include QR Codes, Uniform Product Codes, Serial Numbers or other cargo identification characteristics, for such larger units a user 110 may use the Scan Cargo Unit toggle 2640 to capture the cargo identification characteristic for inbound receipt of the toll and congestion capacity or freight unit. In some implementations and embodiments, an inbound Scan Trailer Unit toggle 2650 option may be used by a user 110 to instruct the system configuration that receipt of a large trailer unit such as an eighteen wheel trailer unit or smaller trailer, may be scanned to identify the toll and congestion capacity or freight unit. In some implementations and embodiments, an inbound Scan Container Unit 2660 toggle may be utilized to track the receipt or location of a shipping container. In some implementations and embodiments, a user 110 may select the outbound package or cargo unit scan module 2693 to scan or take a picture of a package or cargo identification code such as a QR code, Uniform Product code or other identifying package or cargo characteristic to confirm delivery to a delivery address of the toll and congestion capacity or freight toll and congestion capacity unit. In some implementations and embodiments, the user 110 may select the outbound Scan/Picture Package toggle 2670 which captures the identification characteristic of a package or cargo toll and congestion capacity or freight unit once the unit is delivered to the delivery address. In some implementations and embodiments, cargo may include a larger unit structure than a package such as a crate or large movable unit with identification characteristics which may include QR Codes, Uniform Product Codes, Serial Numbers or other cargo identification characteristics, for such larger units a user 110 may use the outbound Scan Cargo Unit toggle 2680 to capture the cargo identification characteristic for outbound receipt of the transformed toll and congestion capacity or freight unit or security. In some implementations and embodiments, an outbound Scan Trailer Unit toggle 2690 option may be used by a user 110 to instruct the system configuration that delivery of a large trailer unit such as an eighteen wheel trailer unit or smaller trailer, may be scanned to identify the toll and congestion capacity or freight unit and confirm delivery. In some implementations and embodiments, an outbound Scan Container Unit 2691 toggle may be utilized to track the delivery or location of a shipping container which has been delivered. In some implementations and embodiments, transformed toll and congestion capacity or freight units or securities may be a subset or superset of the aforementioned in the formation of an open forward market auction for a multi layered network node topology for a forward market of transformed toll and congestion capacity and freight units or securities.

FIG. 27 illustrates an exemplary setting for a package or cargo market configuration 2700 for a transformed toll and congestion capacity or freight toll and congestion capacity unit or security multi layered network node topology in one exemplary implementation of participating, transacting and/or trading transformed toll and congestion capacity or freight capacity units or securities in accordance with some embodiments. In some implementations and embodiments, user interface 210 includes the following elements, or a subset or superset thereof:

exemplary virtual hub combination from a shipping center location (a data transformation) 2711;

exemplary virtual hub origin/from location 2710 with users or freight originators 2712 within the virtual hub location 2710 (a data transformation);

exemplary specification summary of the market, level of service and time of delivery commencement 2727 (a data transformation);

exemplary mode of ground toll and congestion capacity or freight capacity type 2730 (a data transformation);

Exemplary transaction summary of the last trades quantity and price 2728;

exemplary virtual hub destination/to location 2722 and user who is being delivered on the toll and congestion capacity or freight capacity unit 2723 (a data transformation);

exemplary bid/buy quantity title header 2715 for an exemplary virtual toll and congestion capacity or freight toll and congestion capacity unit hub market (a data transformation);

exemplary bid/buy price title header 2716 for an exemplary virtual toll and congestion capacity or freight toll and congestion capacity hub market (a data transformation);

exemplary offer/sell price title header 2719 for an exemplary virtual toll and congestion capacity or freight toll and congestion capacity hub market (a data transformation);

exemplary offer/sell quantity title header 2726 for an exemplary virtual toll and congestion capacity or freight hub market (a data transformation);

exemplary bid/buy quantity 2414 for the best bid quantity from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight toll and congestion capacity virtual hub combination 2711 (a data transformation);

exemplary bid/buy quantity 2713 for the second-best bid quantity from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight capacity virtual hub combination 2711 (a data transformation);

exemplary bid/buy price 2718 for the best bid price from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight capacity virtual hub combination 2711 (a data transformation);

exemplary bid/buy price 2717 for the second-best bid price from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight capacity virtual hub combination 2711 (a data transformation);

exemplary offer/sell price 2721 for the best offer price from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight capacity virtual hub combination 2711 (a data transformation);

exemplary offer/sell price 2720 for the second-best offer price from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight capacity virtual hub combination (a data transformation) 2711;

exemplary offer/sell quantity 2725 for the best offer quantity from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight capacity virtual hub combination (a data transformation) 2711;

exemplary offer/sell quantity 2724 for the second-best offer quantity from a plurality of users 110 for an exemplary respective toll and congestion capacity or freight capacity virtual hub combination (a data transformation) 2711;

exemplary safety dispatch “911” button 2729 to enact video and audio recording of the user 110 environment and dispatch of that information to authorities and system servers.

exemplary hamburger menu button 270 to move back to menu options and settings away from the participation, transaction, trading auction GUI 210 embodiment.

In some implementations and embodiments, the user 110 may enter a transaction quantity and price for toll and congestion capacity or freight capacity units to participate, transact and/or trade by the GUI 210 detecting user 110 contact or audio interface with a bid/buy price 2718 or offer/sell price 2721. The GUI 210 detects user 110 contact with any of the GUI 210 buttons which have been aforementioned. Upon user 110 contact or audio interface with buttons on the GUI 210, instructions are instantiated which allow the user 110 to change the specifications of the respective virtual hub combination 2711. A plurality of prices and markets may be presented based on a plurality of transformed contract specifications. In some implementations and embodiments, the best bid/buy price 2718 may be moving up in price or down in price depending on the market conditions at any given time. In some implementations and embodiments the last trade or last transacted price for a given specification is listed to help the user 110 understand how the market is moving so that the user 110 may submit a competitive offer/selling price 2721 or bid/buying price 2718. In some implementations and embodiments, users 110 may adjust settings of the GUI 210 to show more bid/buying prices 2717 or more offer/selling prices 2720. In some implementations and embodiments the matrix of market quantities and prices 2713, 2714, 2715, 2716, 2717, 2718, 2719, 2720, 2721, 2724, 2725, 2726 may be referred to as market depth in the GUI 210 embodiment. In some implementations and embodiments the number of users 110 may be displayed as user icons 2712 or 2723 for the amount of people logged in which desire to transact, trade or participate in a given virtual hub 2710 to virtual hub 2722 combination for toll and congestion capacity or freight units. In some implementations and embodiments, users 110 may select the toll and congestion capacity mode 2730 such that the user allows a market for only one form of transformed toll and congestion capacity or freight capacity as a commodity or the user 110 may allow the system to show multiple forms of toll and congestion capacity or freight capacity between two virtual toll and congestion capacity hubs 2710, 2711, 2722. In some implementations and embodiments the GUI 210 may detect a user 110 selecting the 911 button 2729 which may activate voice and video recording functions on the mobile or stationary device 111 and transmit the data with a confirmation from the user 110 to the authorities and system servers to provide enhanced security while participating, transacting or trading forward transformed toll and congestion capacity or freight as a commodity or security. In some implementations and embodiments the user may toggle between the GUI 210 market view screen in FIG. 4 and other menu 270 options and settings by the user 110 selecting the hamburger button 270 and the GUI 210 detecting the user 110 input or contact or audio instruction. In some implementations and embodiments the GUI 210 may instantiate instructions in the memory of the mobile computing device 111 which then transmits transformed toll and congestion capacity or freight capacity data through the network 214 or wireless GPS network 215 to call upon instruction routines and instruction sub-routines on the toll and congestion capacity forward market database server 271, virtual hub database server 223, network member database server 222, map routing servers 220, no arbitrage condition database server 220 and/or instructions in the memory of the cloud and local CPUs 210 which all interface together to make one system which may deliver toll and congestion capacity units to users 110 from and to a plurality of virtual hubs 2710, 2722 with a plurality of specifications at specific market prices.

FIG. 28 illustrates an exemplary check in and security database configuration 2800 for a toll and congestion capacity toll and congestion capacity or freight toll and congestion capacity unit multi layered network node topology in one exemplary implementation of participating, transacting and/or trading transformed toll and congestion capacity or freight capacity units or securities in accordance with some embodiments. In some implementations and embodiments, the multi layered network node topology of participating, transacting and/or trading toll and congestion capacity or freight capacity configuration 2800 includes the following security configuration elements, or a subset or superset thereof:

exemplary uniform crime reporting (“UCR”) database 2854 from international agencies who report crime;

exemplary International State or Provincial crime reporting database 2855 from international governments who report crime;

exemplary International National Incident Based Reporting System (“NIBRS”) crime reporting database 2856 from international governments who report crime;

exemplary Interpol crime reporting database 2857 from international governments who report crime which connects National Central Bureaus (“NCBs”);

exemplary International application program interface and ABC (“API/ABC”) crime reporting database 2860 from international governments who report crime;

exemplary national crime reporting database 2858 from international governments who report crime;

exemplary internal system crime reporting database 2859 from crimes which occurred on system;

exemplary facial scan to identify user 2810 against a plurality of crime databases;

exemplary fingerprint scan to identify user 2820 against a plurality of crime databases;

exemplary photo or photo scan to identify user 2830 against a plurality of crime databases;

exemplary voice scan to identify user 2810 against a plurality of crime databases;

exemplary computing device unit GUI 210 to display method of multi layered network node topology for forward market of toll and congestion capacity and freight units.

hamburger menu toggle 270 to move between different application configurations;

exemplary driver or freight transport or freight or transport seller unit user interface 2851 to confirm identity verification against a plurality of crime databases;

exemplary passenger unit or freight toll and congestion capacity unit user interface 2852 to confirm identity verification against a plurality of crime databases;

exemplary handshake verification user interface 2853 to confirm both buyer and seller of toll and congestion capacity or freight units were correctly verified against crime databases;

In some implementations and embodiments, a plurality of crime databases UCR Database 2854, State and Province Database 2855, NIBRS database 2856, INTERPOL database 2857, API/ABC database 2860, National database 2858, Internal system database 2859 are used to confirm a user 110, has been confirmed not to have criminal history in accordance with instructions on the method and system. In some implementations and embodiments, toll and congestion capacity or freight toll and congestion capacity unit security may be a subset or superset of the aforementioned in the formation of an open forward market auction for a multi layered network node topology for a forward market of toll and congestion capacity and freight units. Such security checks are standard in airports, but they are not automated and they are not utilized in other modes of toll and congestion capacity which degrades the overall safety of other toll and congestion capacity methods if they are not utilized. In some implementations and embodiments, the check in instructions may reject a user from confirmed verified transport if they fail the plurality of safety checks. In some implementations and embodiments, confirmed no crime history users 110 do not have activity reported in the plurality of crime databases UCR Database 2854, State and Province Database 2855, NIBRS database 2856, INTERPOL database 2857, API/ABC database 2860, National database 2858, Internal system database 2859 and are confirmed to transport verified status 2853 in the system.

FIG. 29 illustrates an exemplary user accounting configuration 2900 for a transformed toll and congestion capacity or freight unit or security multi layered network node topology in one exemplary implementation of participating, transacting and/or trading transformed toll and congestion capacity or freight capacity unit auctions in accordance with some embodiments. In some implementations and embodiments, the multi layered network node topology of participating, transacting and/or trading transformed toll and congestion capacity or freight capacity configuration 2900 includes the following accounting elements, or a subset or superset thereof:

computing device unit GUI 210 to display method of multi layered network node topology for forward market of toll and congestion capacity and freight toll and congestion capacity units;

exemplary hamburger menu toggle 270 to move between different application configurations;

exemplary account button 2910 to edit or confirm user account data;

exemplary deposit button 2920 to add transaction funds or transaction currency or transaction balances to the user account;

exemplary deposit method button 2930 to add transaction funds or transaction currency or transaction balances to the user account through Debit, Credit, Cash, Check, virtual currency, digital currency or a plurality of other payment methods;

exemplary withdrawal button 2940 to send transaction funds or transaction currency or transaction balances to the user account in a different institution;

exemplary withdrawal method button 2970 to send transaction funds or transaction currency or transaction balances to the user account at a different institution through Debit, Credit, Cash, Check, virtual currency, digital currency or a plurality of other payment methods;

exemplary balances button 2950 to confirm user account balances;

exemplary tax button 2960 to track user account activity for taxation reporting;

exemplary month to date tax reporting button 2980;

exemplary year to date tax reporting button 2990;

exemplary prior year tax reporting button 2991;

exemplary “911” security button 2991;

exemplary Network Member Database Server 160;

exemplary cloud and CPU and Network configuration 190 to send and receive Network Member account data;

In some implementations and embodiments, user account 2910 data may be displayed with voice or screen or non-screen computing devices with instructions from the GUI 210 in accordance with instructions on the method and system. In some implementations and embodiments, user deposit 2920 data may be displayed with voice or screen or non-screen computing devices with instructions from the GUI 210 in accordance with instructions on the method and system. In some implementations and embodiments, user deposit method 2930 data such as Debit, Credit, Cash, Check, virtual currency, digital currency or a plurality of other payment methods may be displayed with voice or screen or non-screen computing devices with instructions from the GUI 210 in accordance with instructions on the method and system. In some implementations and embodiments, user withdrawal 2940 data may be displayed with voice or screen or non-screen computing devices with instructions from the GUI 210 in accordance with instructions on the method and system. In some implementations and embodiments, user withdrawal method 2970 data such as Debit, Credit, Cash, Check, virtual currency, digital currency or a plurality of other payment methods may be displayed with voice or screen or non-screen computing devices with instructions from the GUI 210 in accordance with instructions on the method and system to place money in the system account into a different institution specified by the user 110. In some implementations and embodiments, user balances 2950 data may be displayed with voice or screen or non-screen computing devices with instructions from the GUI 210 in accordance with instructions on the method and system. In some implementations and embodiments, user tax button 2960 data may be displayed with voice or screen or non-screen computing devices with instructions from the GUI 210 in accordance with instructions on the method and system. In some implementations and embodiments, user month to date tax data button 2980, year to date tax data button 2990, prior year tax data button 2991 may be displayed with voice or screen or non-screen computing devices with instructions from the GUI 210 in accordance with instructions on the method and system. In some implementations and embodiments, the accounting and tax information may be stored in the Network Member Database Server 160 and transmitted through the cloud, network and CPUs 190 to the GUI computing device 210. In some implementations and embodiments, toll and congestion capacity or freight unit accounting and fund interfaces may be a subset or superset of the aforementioned in the formation of an open forward market auction for a multi layered network node topology for a forward market of toll and congestion capacity and freight units.

FIG. 30 illustrates an exemplary network configuration 3000 for a toll and congestion capacity or freight toll and congestion capacity unit multi layered network node topology in one exemplary implementation of participating, transacting and/or trading toll and congestion capacity or freight capacity unit auctions in accordance with some embodiments. In some implementations and embodiments, the multi layered network node topology of participating, transacting and/or trading toll and congestion capacity or freight capacity configuration 3000 includes the following accounting elements, or a subset or superset thereof:

exemplary Wireless GPS Network and Server 3083;

exemplary Wireless computing device that is audio, video, screen or non-screen interfaced 3082;

exemplary Network Member Database Server 3050;

exemplary Toll and congestion capacity Forward Market Database Server 3060;

exemplary No Arbitrage Condition Database Server 3070;

exemplary Virtual Hub Database Server 3080;

exemplary Network, Network Cloud, and local CPUs 3081;

exemplary Network Multi Layered Network Virtual Hub Node Topology for forward market toll and congestion capacity of freight unit auctions 3010, 3020, 3030, 3040.

In some implementations and embodiments, the network topology 3010 may utilize a voice or screen or non-screen computing device 3082 to interface with system and method instructions over a Network and Network Cloud and Networked CPUs 3081 to use instructions on CPUs to order a constrained or unconstrained virtual hub network topology auction over two or more virtual hub nodes 3010, 3020, 3030, 3040 over one or multiple modes of toll and congestion capacity or freight with instructions and data from the Virtual Hub Database Server 3080, the No Arbitrage Condition Database Server 3070, the Toll and congestion capacity Forward Market Database Server 3060, the Network Member Database Server 3050 and the Wireless GPS Network Server 3083. Network Data may be displayed with voice or screen or non-screen computing devices with instructions from the GUI 210 in accordance with instructions on the method and system.

FIG. 31 illustrates an exemplary network configuration 3100 integrating the disclosed method and system as a layer on a traditional third party map software. In some implementations and embodiments, the multi layered network node topology of participating, transacting and/or trading transformed toll and congestion capacity or freight capacity configuration 3100 includes the following accounting elements, or a subset or superset thereof:

exemplary computing device 3105;

exemplary route input by user 3175;

exemplary route node structure 3190 to satisfy user route request 3175;

exemplary alternative route node structure 3180 to satisfy user route request 3175 with associated time 3180;

exemplary time estimate 3185 for route 3190;

exemplary live auction price value 3110 for route 3190;

exemplary alternative live auction price value 3115 for route 3180;

exemplary navigation mode button 3171;

exemplary game mode button 3172;

exemplary date and time modification button 3195 for disclosed route 3175;

exemplary transformed forward toll and congestion capacity unit auction value and modification feed 3115 and selection GO 3145 button to transact the given route with a basic toll and congestion capacity unit or security feature and characteristic for one route 3190 that satisfies the user route request 3175;

exemplary alternative transformed forward toll and congestion capacity unit auction value and modification feed 3120 and selection GO 3150 button to transact the given route with a basic toll and congestion capacity unit or security feature and characteristic for one alternative route 3180 that satisfies the user route request 3175;

exemplary transformed forward toll and congestion capacity unit auction value and modification feed 3125 and selection GO 3155 button to transact the given route with an intermediate toll and congestion capacity unit or security feature and characteristic for one route 3190 that satisfies the user route request 3175;

exemplary alternative transformed forward toll and congestion capacity unit auction value and modification feed 3130 and selection GO 3160 button to transact the given route with an intermediate toll and congestion capacity unit or security feature and characteristic for one alternative route 3180 that satisfies the user route request 3175;

exemplary transformed forward toll and congestion capacity unit auction value and modification feed 3135 and selection GO 3165 button to transact the given route with a premium toll and congestion capacity unit or security feature and characteristic for one route 3190 that satisfies the user route request 3175;

exemplary alternative transformed forward toll and congestion capacity unit auction value and modification feed 3140 and selection GO 3165 button to transact the given route with a premium toll and congestion capacity unit or security feature and characteristic for one alternative route 3180 that satisfies the user route request 3175;

exemplary market display feature 3170 as an overlay onto map routing for user requests 3175;

In some implementations and embodiments, map routing interfaces 3105 such as Apple Maps or TomTom or another third party, may integrate the disclosed method and system to display the transformed forward toll and congestion capacity unit or security market auction price along a various route given various virtual hub topologies 1800 over the user 110 defined route request 3175. The computing device 3105 may disclose over visual, audio or other communication methods the forward transformed toll and congestion capacity unit auction price 3110 on a given route 3190. In yet other embodiments, the disclosed toll and congestion capacity unit transformation may communicate the forward transformed toll and congestion capacity unit or security auction price 3115 of an alternative route 3180 such that a user may select either route 3190 or 3180 based on the disclosed method and system price 3110 or 3115 which was generated by instructions from a plurality of users between two virtual hubs on the user defined route 3175. The disclosed forward market toll and congestion capacity unit auction may be communicated on an on demand basis representing the current time and day or on a forward basis by changing the Date/Time 3195 user interface button feature to represent the then current market pricing for future time intervals on a plurality of given routes 3190 and 3180 along the user requested virtual hub combination 3175. Virtual hubs may represent the end points of a route defined by the user 3175 or virtual hubs may represent points along a given route but not including the endpoints or virtual hubs may represent points not along the route the user defined 3175. Virtual hub combinations transform toll and congestion capacity units into a forward market which allow users of the method and system to transact in the physical market by either delivering transformed toll and congestion capacity units as a driver of a vehicle or capacity holder or by receiving them as a passenger or package if the unit is a package rather than a person. A toll and congestion capacity unit or security represents space which may be filled by a person or a package. Further the forward transformed toll and congestion capacity unit market auction 3170 overlay may be a layer on traditional GPS map routing software or as an alternative to time based routing or mileage based routing. The forward toll and congestion capacity unit market specification such as “Basic” 3115, 3120 or “Intermediate” 3125, 3130 or “Premium” 3135, 3140 may also have a plurality of other characteristics or levels which form the basis of a fungible transformed contract or substitutable contract between users which is exchangeable with the same terms and conditions if one user is unable to fulfil their contract obligations for the transformed toll and congestion capacity unit. In some implementations and embodiments, the navigation mode 3171 may move the user to turn by turn directions along the price based navigation route 3190. In some implementations and embodiments, the game mode 3172 may move the user to a game based overlay on the price based navigation route 3190. In some implementations and embodiments, the market mode 3170 may move the user to a market based overlay on the priced based navigation route 3190.

The disclosed method and system of a transformed toll and congestion capacity unit may be fully functional as a layer in map routing software 3100 or as a stand alone application 200, 300, etc.

In some implementations and embodiments, the disclosed method and system toll and congestion capacity unit auction price 3110 and 3115 has two prices or more in other embodiments. Two route prices 3110 are disclosed at $3 and $3.10. The former price of $3 is the price where a user is willing to buy or pay for a toll and congestion capacity unit along the given route 3190. The later price of $3.10 is the price at which a user is willing to sell a toll and congestion capacity unit along the given route 3190. The instructions of the auction may match the highest bidding price of $3 with the lowest selling price in the price queue when the prices match. In other words, in the exemplary embodiment, if a user wanted to sell a toll and congestion capacity unit at the current forward market auction queue 3110 on route 3190, the user would enter a price of $3 which is the current highest bidding price in the method and system queue 3110. By way of further example, another user may desire to buy a toll and congestion capacity unit on the forward transformed toll and congestion capacity unit auction method and system on route 3190, to match, the user would enter a price of $3.10 which is the lowest selling price of a seller on the forward market toll and congestion capacity unit auction method and system.

FIG. 32 illustrates another exemplary network configuration 3200 integrating the disclosed method and system as a layer on another traditional third party map software. In some implementations and embodiments, the multi layered network node topology of participating, transacting and/or trading toll and congestion capacity or freight capacity configuration 3200 includes the following accounting elements, or a subset or superset thereof:

exemplary computing device 3205;

exemplary route input by user 3210;

exemplary route node structure 3295 to satisfy user route request 3210;

exemplary alternative route node structure 3230 to satisfy user route request 3210 with associated time;

exemplary time estimate 3225 for route 3295;

exemplary navigation mode button 3291;

exemplary game mode button 3292;

exemplary market mode button 3293;

exemplary live auction price value 3220 for route 3295;

exemplary alternative live auction price value 3230 for route 3230;

exemplary date and time modification button 3296 for disclosed route 3210;

exemplary transformed forward toll and congestion capacity unit or security auction value and modification feed 3235 and selection GO 3265 button to transact the given route with a basic toll and congestion capacity unit feature and characteristic for one route 3295 that satisfies the user route request 3210;

exemplary alternative transformed forward toll and congestion capacity unit or security auction value and modification feed 3240 and selection GO 3270 button to transact the given route with a basic toll and congestion capacity unit feature and characteristic for one alternative route 3230 that satisfies the user route request 3210;

exemplary transformed forward toll and congestion capacity unit or security auction value and modification feed 3245 and selection GO 3275 button to transact the given route with an intermediate toll and congestion capacity unit feature and characteristic for one route 3295 that satisfies the user route request 3210;

exemplary alternative transformed forward toll and congestion capacity unit or security auction value and modification feed 3250 and selection GO 3280 button to transact the given route with an intermediate toll and congestion capacity unit feature and characteristic for one alternative route 3230 that satisfies the user route request 3210;

exemplary transformed forward toll and congestion capacity unit or security auction value and modification feed 3255 and selection GO 3285 button to transact the given route with a premium toll and congestion capacity unit feature and characteristic for one route 3295 that satisfies the user route request 3210;

exemplary alternative transformed forward toll and congestion capacity unit or security auction value and modification feed 3260 and selection GO 3290 button to transact the given route with a premium transformed toll and congestion capacity unit feature and characteristic for one alternative route 3230 that satisfies the user route request 3210;

exemplary market display feature 3215 as an overlay onto map routing for user requests 3210;

In some implementations and embodiments, map routing interfaces 3205 such as Google Maps or Garmin or another third party navigation method, may integrate the disclosed method and system to display the transformed forward toll and congestion capacity unit or security market auction price along a various route given various virtual hub topologies 1800 over the user 110 defined route request 3210. The computing device 3205 may disclose over visual, audio or other communication methods the forward transformed toll and congestion capacity unit or security auction price 3220 on a given route 3295. In yet other embodiments, the disclosed toll and congestion capacity unit transformation may communicate the forward transformed toll and congestion capacity unit auction price 3230 of an alternative route 3230 such that a user may select either route 3295 or 3230 based on the disclosed method and system price 3230 or 3220 which was generated by instructions from a plurality of users between two virtual hubs on the user defined route 3210 and instructions to generate a price queue for buyers and sellers of toll and congestion capacity units long given routes. In some implementations and embodiments, the user(s) 110 may alter the date 3296 such that the transformed toll and congestion capacity unit or security may be updated with user 110 submitted prices 3235 for forward looking time periods. The disclosed forward market transformed toll and congestion capacity unit or security auction may be communicated on an on demand basis representing the current time and day or on a forward basis by changing the Date/Time 3296 user interface button feature to represent the then current market pricing for future time intervals on a plurality of given routes 3295 and 3230 along the user requested virtual hub combination 3210. Virtual hubs may represent the end points of a route defined by the user 3210 or virtual hubs may represent points along a given route but not including the endpoints or virtual hubs may represent points not along the route the user defined 3210. Virtual hub combinations transform toll and congestion capacity units or securities into a forward market which allow users of the method and system to transact in the physical market by either delivering transformed toll and congestion capacity units as a driver of a vehicle or capacity holder or by receiving them as a passenger or package if the unit is a package rather than a person. A transformed toll and congestion capacity unit represents space which may be filled by a person or a package or vehicle or ship or transportation device. Further the forward transformed toll and congestion capacity unit market auction 3215 overlay may be a layer on traditional GPS map routing software as an alternative to time based routing. The forward toll and congestion capacity unit market specification such as “Basic” 3235, 3240 or “Intermediate” 3245, 3250 or “Premium” 3255, 3260 may also have a plurality of other characteristics or levels which form the basis of a fungible contract or substitutable contract between users which is exchangeable with the same terms and conditions if one user is unable to fulfil their contract obligations for the transformed toll and congestion capacity unit. In some implementations and embodiments, the navigation mode 3291 may move the user to turn by turn directions along the price based navigation route 3295. In some implementations and embodiments, the game mode 3292 may move the user to a game based overlay on the price based navigation route 3295. In some implementations and embodiments, the market mode 3293 may move the user to a market based overlay on the priced based navigation route 3295.

The disclosed method and system of a transformed toll and congestion capacity unit may be fully functional as a layer in map routing software 3200 or as a stand alone application 200, 300, etc.

In some implementations and embodiments, the disclosed method and system transformed toll and congestion capacity unit or security auction price 3220 and 3230 has two prices or more in other embodiments. Two route prices 3220 are disclosed at $3 and $3.10. The former price of $3 is the price where a user is willing to buy or pay for a toll and congestion capacity unit along the given route 3295. The later price of $3.10 is the price at which a user is willing to sell a toll and congestion capacity unit along the given route 3295. The instructions of the auction may match the highest bidding price of $3 with the lowest selling price in the price queue when the prices match. In other words, in the exemplary embodiment, if a user wanted to sell a toll and congestion capacity unit at the current forward market auction queue 3220 on route 3295, the user would enter a price of $3 which is the current highest bidding price in the method and system queue 3220. By way of further example, another user may desire to buy a transformed toll and congestion capacity unit on the forward transformed toll and congestion capacity unit or security auction method and system on route 3295, to match, the user would enter a price of $3.10 which is the lowest selling price of a seller on the forward market transformed toll and congestion capacity unit auction method and system.

FIG. 33 illustrates another exemplary network configuration 3300 integrating the disclosed method and system as a layer on another traditional third party map software. In some implementations and embodiments, the multi layered network node topology of participating, transacting and/or trading toll and congestion capacity or freight capacity configuration 3300 includes the following accounting elements, or a subset or superset thereof:

exemplary computing device 3335;

exemplary route node structure 3340 to satisfy user route requests with associated time and price;

exemplary alternative route node structure 3345 to satisfy user route request with associated time and price;

exemplary alternative route node structure 3350 to satisfy user route request with associated time and price;

exemplary live auction price value 3305 for price based route 3340;

exemplary navigation mode button 3391;

exemplary game mode button 3392;

exemplary market mode button 3393;

exemplary go 3330 button to transact or modify the price based routing;

exemplary go 3325 button to transact or modify the price based routing;

exemplary go 3320 button to transact or modify the price based routing;

exemplary alternative live auction price value 3310 for route 3345;

exemplary alternative live auction price value 3315 for route 3350;

exemplary date and time modification button 3355 for disclosed route 3340;

exemplary date and time modification button 3360 for disclosed route 3345;

exemplary date and time modification button 3365 for disclosed route 3350;

In some implementations and embodiments, map routing interfaces 3335 such as Waze Maps or another third party, may integrate the disclosed method and system to display the transformed forward toll and congestion capacity unit market auction price along a various route given various virtual hub topologies 1800 over the user 110 defined route requests. The computing device 3335 may disclose over visual, audio or other communication methods the forward transformed toll and congestion capacity unit or security auction price 3305 on a given route 3340. In yet other embodiments, the disclosed toll and congestion capacity unit transformation may communicate the forward transformed toll and congestion capacity unit auction price 3310 of an alternative route 3345 such that a user may select either route 3340 or 3345 or 3350 based on the disclosed method and system price 3305 or 3310 or 3315 which was generated by instructions from a plurality of users between two virtual hubs on the user defined route and instructions to generate a price queue for buyers and sellers of toll and congestion capacity units along given routes. The disclosed forward market transformed toll and congestion capacity unit or security auction may be communicated on an on demand basis representing the current time and day or on a forward basis by changing the Date/Time 3340, 3360, 3365 user interface button feature to represent the then current market pricing for future time intervals on a plurality of given routes 3340 or 3345 or 3350 along the user requested virtual hub combination. In some implementations and embodiments, the user(s) 110 may alter the date 3355 such that the transformed toll and congestion capacity unit or security may be updated with user 110 submitted prices 3305 for forward looking time periods. Virtual hubs may represent the end points of a route defined by the user or virtual hubs may represent points along a given route but not including the endpoints or virtual hubs may represent points not along the route the user defined. Virtual hub combinations transform toll and congestion capacity units into a forward market which allow users of the method and system to transact in the physical market by either delivering toll and congestion capacity units as a driver of a vehicle or capacity holder or by receiving them as a passenger or package if the unit is a package rather than a person. A toll and congestion capacity unit represents space which may be filled by a person or a package. Further the forward toll and congestion capacity unit market auction 3305 overlay may be a layer on traditional GPS map routing software or as an alternative to time based routing. The forward toll and congestion capacity unit market specification such as “Basic” 3305 may also have a plurality of other transformed characteristics or levels which form the basis of a fungible contract or substitutable contract specifications between users which is exchangeable with the same terms and conditions if one user is unable to fulfil their contract obligations for the transformed toll and congestion capacity unit or security. In some implementations and embodiments, the navigation mode 3391 may move the user to turn by turn directions along the price based navigation route 3350. In some implementations and embodiments, the game mode 3392 may move the user to a game based overlay on the price based navigation route 3340. In some implementations and embodiments, the market mode 3393 may move the user to a market based overlay on the priced based navigation route 3350.

The disclosed method and system of a transformed toll and congestion capacity unit may be fully functional as a layer in map routing software 3300 or as a stand alone application 200, 300, etc.

In some implementations and embodiments, the disclosed method and system toll and congestion capacity unit auction price 3305 and 3310 and 3315 has two prices or more in other embodiments. Two route prices 3305 are disclosed at $3 and $3.10. The former price of $3 is the price where a user is willing to buy or pay for a toll and congestion capacity unit along the given route 3340. The later price of $3.10 is the price at which a user is willing to sell a toll and congestion capacity unit along the given route 3340. The instructions of the auction may match the highest bidding price of $3 with the lowest selling price in the price queue when the prices match. In other words, in the exemplary embodiment, if a user wanted to sell a toll and congestion capacity unit at the current forward market auction queue 3305 on route 3340, the user would enter a price of $3 which is the current highest bidding price in the method and system queue 3305. By way of further example, another user may desire to buy a toll and congestion capacity unit on the forward toll and congestion capacity unit auction method and system on route 3340, to match, the user would enter a price of $3.10 which is the lowest selling price of a seller on the forward market toll and congestion capacity unit auction method and system.

FIG. 34 illustrates another exemplary network configuration 3400 integrating the disclosed method and system as a layer on another traditional third party map software. In some implementations and embodiments, the multi layered network node topology of participating, transacting and/or trading transformed toll and congestion capacity or freight capacity unit or security configuration 3400 includes the following accounting elements, or a subset or superset thereof:

exemplary computing device 3405;

exemplary route 3410;

exemplary live auction price value 3430 for route 3410;

exemplary alternative live auction price value 3425 for route 3425;

exemplary navigation mode button 3491;

exemplary game mode button 3492;

exemplary market mode button 3493;

exemplary date and time modification button 3435 for disclosed route 3410;

exemplary mileage estimate 3455 for disclosed route 3410;

exemplary route estimate 3450 for disclosed route 3410;

exemplary transformed forward toll and congestion capacity unit auction value and modification feed 3415 and selection GO 3440 button to transact the given route with a basic toll and congestion capacity unit or security feature and characteristic for one route 3425 that satisfies the user route request;

exemplary transformed forward toll and congestion capacity unit or security auction value and modification feed 3420 and selection GO 3445 button to transact the given route with a premium toll and congestion capacity unit feature and characteristic for one route 3410 that satisfies the user route request;

In some implementations and embodiments, the navigation mode 3491 may move the user to turn by turn directions along the price based navigation route 3410. In some implementations and embodiments, the game mode 3492 may move the user to a game based overlay on the price based navigation route 3410. In some implementations and embodiments, the market mode 3493 may move the user to a market based overlay on the priced based navigation route 3410.

FIG. 35 illustrates another exemplary network configuration 3500 integrating the disclosed method and system as a layer on another traditional third party map software in the setting of a vehicle GPS navigation system. In some implementations and embodiments, the multi layered network node topology of participating, transacting and/or trading toll and congestion capacity or freight capacity configuration 3500 includes the following accounting elements, or a subset or superset thereof:

exemplary computing device 3550;

exemplary vehicle toll and congestion capacity unit carrier unit 3505;

exemplary vehicle toll and congestion capacity unit steering wheel 3510;

exemplary navigation mode button 3581;

exemplary game mode button 3580;

exemplary market mode button 3530;

exemplary user of toll and congestion capacity unit as seller or driver 3515;

exemplary user route request address information 3545;

exemplary date and time modification button 3540 for disclosed route 3545;

exemplary transformed forward toll and congestion capacity unit auction value and modification feed 3525 and selection GO 3535 button to transact the given route with a basic toll and congestion capacity unit feature and characteristic for one route 3545 that satisfies the user route request;

exemplary live auction price value 3555 for price based route 3555;

exemplary live auction price value 3560 for price based alternative route 3560;

exemplary market layer routing overlay 3530;

In some implementations and embodiments, the disclosed method and system transformed toll and congestion capacity unit or security auction market layer may be in a vehicle unit GPS navigation system 3550. In some implementations and embodiments, the user 3515 may input driving address instructions 3545 that have an origin location and a destination location. In some implementations and embodiments, the user 3515 may communicate with the computing device 3550 through a touchscreen 3520 or and audio interface or another interface. In some implementations and embodiments the user 3515 may edit the date/time 3540 button to communicate the market auction price based route 3555 from on demand or current time to a forward time or date. Market auction based pricing 3555 may vary by date and time due to a plurality of market factors. In some implementations and embodiments the user 3515 may edit the market based auction price for the toll and congestion capacity units by selecting the market feature button 3525. In some implementations and embodiments the user 3515 may select a give toll and congestion capacity unit auction price to transact by selecting the go button 3535. In some implementations and embodiments, the navigation mode 3581 may move the user to turn by turn directions along the price based navigation route 3555. In some implementations and embodiments, the game mode 3580 may move the user to a game based overlay on the price based navigation route 3555. In some implementations and embodiments, the market mode 3530 may move the user to a market based overlay on the priced based navigation route 3555.

In some implementations and embodiments, the disclosed method and system toll and congestion capacity unit auction price 3555 and 3560 has two prices or more in other embodiments. Two route prices 3555 are disclosed at $3 and $3.10. The former price of $3 is the price where a user is willing to buy or pay for a toll and congestion capacity unit along the given route 3545. The later price of $3.10 is the price at which a user is willing to sell a toll and congestion capacity unit along the given route 3545. The instructions of the auction may match the highest bidding price of $3 with the lowest selling price in the price queue when the prices match. In other words, in the exemplary embodiment, if a user 3515 wanted to sell a toll and congestion capacity unit at the current forward market auction queue 3555 on route 3545, the user 3515 would enter a price of $3 which is the current highest bidding price in the method and system queue 3555. By way of further example, another user may desire to buy a toll and congestion capacity unit on the forward transformed toll and congestion capacity unit or security auction method and system on route 3545, to match, the user would enter a price of $3.10 which is the lowest selling price of a seller on the forward market transformed toll and congestion capacity unit or security auction method and system. In some implementations and embodiments, alternative routes based on prices in alternative toll and congestion capacity unit auctions 3560 may have different prices based on supply and demand conditions. In some implementations and embodiments the market based routing layer 3530 serves as an alternative to time based routing or mileage based routing which are fundamentally different premises. In some implementations and embodiments, the overall software system 3505 and associated instructions may ask the user 3515 with visual or audio interface if the user 110 would like to monetize there toll and congestion routes upon starting any navigation sequence for transformed toll and congestion capacity units or securities.

FIG. 36 illustrates another exemplary network configuration 3600 integrating the disclosed method and system as a game layer on another internal mapping system or traditional third party map system in the setting of a mobile computing device. In some implementations and embodiments, the multi layered network node topology of participating, transacting and/or trading transformed toll and congestion capacity or freight capacity unites or securities for price based navigation configuration 3600 includes the following accounting elements, or a subset or superset thereof:

exemplary computing device 3605;

exemplary game overlay user score 3610;

exemplary game overlay user power 3615;

exemplary game overlay SOV (single occupancy vehicle) count 3620;

exemplary game overlay weapon strength 3625;

exemplary game overlay account balance 3630;

exemplary game overlay passenger pick ups 3688;

exemplary game overlay Single Occupancy Vehicle target 3645;

exemplary game overlay Single Occupancy Vehicle weapon 3650;

exemplary game overlay GPS standard map view 3655;

exemplary game overlay augmented or mixed reality view 3660;

exemplary game overlay passenger mode 3687;

exemplary game overlay fire button 3665;

exemplary game overlay multi-purpose direction button 3670;

exemplary game overlay go button 3680;

exemplary game overlay stop button 3675;

exemplary navigation overlay button 3686;

exemplary game overlay button 3689;

exemplary market overlay button 3685;

exemplary market overlay weapon selection button 3683, 3682, 3681, 3694;

exemplary market overlay aim finder toggle 3684.

In some implementations and embodiments, the game overlay 3689 awards score and points for destroying the single occupancy vehicle 3620, compute and distribute positive or negative toll and congestion capacity unit game auction strategy points 3610 or power 3615 or rewards 3630 based on any superset combination or subset combination of price 3635, route mileage 3640, number of single occupancy vehicles destroyed or passed 3620, number of passengers 3688, route time estimates 3640, toll and congestion capacity unit route 3640, toll and congestion capacity unit specifications 3415, toll and congestion capacity unit model type 4000 based on model type and age 4000, toll and congestion capacity unit make type 4000, toll and congestion capacity unit age 4000, matched toll and congestion capacity unit specification 800 and 620, matched toll and congestion capacity unit fuel type 4000, matched toll and congestion capacity unit emission specification 4000, cumulative user toll and congestion capacity unit specifications 4100, toll and congestion capacity unit rating 4100, toll and congestion capacity unit safety 4100, toll and congestion capacity unit time 4100, toll and congestion capacity unit delay, toll and congestion capacity unit driver rating 4100, toll and congestion capacity unit rider rating 4100, toll and congestion capacity unit timeliness relative to contract specification 4100.

In some implementations and embodiments, the game overlay 3689 may use a plurality of weapon or scoring configurations such as a rifle 3683, an axe 3681, a flower gift 3682, a X logo 3694 to take away points or gain points from other users on the system. In some implementations and embodiments the scoring may be independent of other players on the system, but dependent on the users actions in the game overlay 3689. In some implementations and embodiments a selected weapon 3650 may be used to destroy single occupancy vehicles. In some implementations and embodiments the user may accelerate with the go button 3680 to avoid an attack or fire. In some implementations and embodiments the user may slow down or stop with the stop button 3675 to avoid enemy fire or attack. In some implementations and embodiments, the stop button 3675 may interface with an autonomous driving system of a vehicle to pick up passengers along a price based navigation route to increase the score of the player 3610 and increase the balances 3630 by earning money on the system. In some implementations and embodiments user(s) may be identified by the X logo 3694 or by a person logo who is a bidder on the priced based navigation route 3640 to increase score and balances 3630. In some implementations and embodiments user(s) may scan navigation view 3655 or augmented reality view 3660 to look for single occupancy vehicle targets or X logo(s) 3694 or 3645 for users who are bidding on the price based navigation route 3640.

In some implementations and embodiments, the strategy of the priced based navigation game overlay is to pick up as many passengers or bidders as possible along the price based navigation route 3640, destroy as many single occupancy vehicles along the price based navigation route 3640 and to give flowers 3682 and rewards to toll and congestion capacity unit providers who have more than one person in the vehicle along the price based navigation route 3640. In some implementations and embodiments user(s) may work independently or collectively in tribes to maximize user score in strategy.

FIG. 37 illustrates another exemplary network configuration 3700 integrating the disclosed method and system as a game layer on another internal mapping navigation system or traditional third party navigation map system in the setting of a mobile computing device. In some implementations and embodiments, the multi layered network node topology of participating, transacting and/or trading toll and congestion capacity or freight capacity for price based navigation configuration 3700 includes the following accounting elements, or a subset or superset thereof:

exemplary computing device 3705;

exemplary game overlay user score 3710;

exemplary game overlay user power 3720;

exemplary game overlay SOV (single occupancy vehicle) count 3730;

exemplary game overlay weapon strength 3715;

exemplary game overlay account balance 3725;

exemplary game overlay passenger pick ups 3788;

exemplary game overlay Single Occupancy Vehicle target 3735;

exemplary game overlay Single Occupancy Vehicle weapon 3771;

exemplary game overlay GPS standard map view 3740;

exemplary game overlay augmented or mixed reality view 3745;

exemplary game overlay passenger mode 3790;

exemplary game overlay fire button 3750;

exemplary game overlay multi-purpose direction button 3755;

exemplary game overlay go button 3767;

exemplary game overlay stop button 3760;

exemplary navigation overlay button 3765;

exemplary game overlay button 3792;

exemplary market overlay button 3768;

exemplary market overlay weapon selection button 3775, 3770, 3769, 3796;

exemplary market overlay aim finder toggle 3780.

In some implementations and embodiments, the game overlay view 3768 of the price based navigation system 3705 may alert the user to a single occupancy vehicle 3735 which would then be a target for the user to use a weapon 3771, 3775, 3769 to destroy the single occupancy vehicle to increase user score 3710. In some implementations and embodiments, the user may identify a vehicle as having more than one passenger in the vehicle and therefore award or gift flowers 3770 to the vehicle or toll and congestion capacity user in the price based navigation game strategy. In some implementations and embodiments, the user may use a weapon 3771 against a single occupancy vehicle 3735 at which point the vehicle would explode and the passenger would be left without a vehicle in the augmented reality view 3745 or GPS view 3740. In some implementations and embodiments, the user may award flowers 3770 to a vehicle with more than one passenger to increase their score 3710 and the score of the user that has more than one passenger in their vehicle.

FIG. 38 illustrates another exemplary network configuration 3800 integrating the disclosed method and system as a game layer on another internal mapping navigation system or traditional third party navigation map system in the setting of a mobile computing device. In some implementations and embodiments, the multi layered network node topology of participating, transacting and/or trading toll and congestion capacity or freight capacity for price based navigation configuration 3800 includes the following accounting elements, or a subset or superset thereof:

exemplary computing device 3805;

exemplary game overlay user score 3810;

exemplary game overlay user power 3815;

exemplary game overlay SOV (single occupancy vehicle) count 3820;

exemplary game overlay weapon strength 3825;

exemplary game overlay account balance 3830;

exemplary game overlay passenger pick ups 3888;

exemplary game overlay flower gift 3896;

exemplary game overlay GPS standard map view 3845;

exemplary game overlay augmented or mixed reality view 3840;

exemplary game overlay passenger mode 3885;

exemplary game overlay fire button 3850;

exemplary game overlay multi-purpose direction button 3855;

exemplary game overlay go button 3865;

exemplary game overlay stop button 3860;

exemplary navigation overlay button 3866;

exemplary game overlay button 3897;

exemplary market overlay button 3868;

exemplary market overlay weapon selection button 3869, 3870, 3875, 3898;

exemplary market overlay aim finder toggle 3880.

In some implementations and embodiments, the game overlay view 3897 of the price based navigation system 3805 may alert the user to a vehicle with more than one passenger 3899 which would then be a way for the user to gift a flower to the other user 3899.

FIG. 39 illustrates another exemplary network configuration 3900 integrating the disclosed method and system as a game layer on another internal mapping navigation system or traditional third party navigation map system in the setting of a mobile computing device. In some implementations and embodiments, the multi layered network node topology of participating, transacting and/or trading toll and congestion capacity or freight capacity for price based navigation configuration 3900 includes the following accounting elements, or a subset or superset thereof:

exemplary computing device 3905;

exemplary game overlay user score 3910;

exemplary game overlay user power 3915;

exemplary game overlay SOV (single occupancy vehicle) count 3920;

exemplary game overlay weapon strength 3925;

exemplary game overlay account balance 3930;

exemplary game overlay passenger pick ups 3988;

exemplary game overlay weapon 3968;

exemplary game overlay GPS standard map view 3940;

exemplary game overlay augmented or mixed reality view 3967;

exemplary game overlay passenger mode 3985;

exemplary game overlay fire button 3945;

exemplary game overlay multi-purpose direction button 3950;

exemplary game overlay go button 3961;

exemplary game overlay stop button 3960;

exemplary navigation overlay button 3955;

exemplary market overlay button 3962;

exemplary market overlay weapon selection button 3963, 3966, 3965, 3979;

exemplary market overlay aim finder toggle 3964;

exemplary user in augmented reality view who has had their single occupancy vehicle destroyed 3935.

In some implementations and embodiments, the game overlay view 3905 of the price based navigation system 3905 may show a user who has had their single occupancy vehicle destroyed 3935 which increases the score of the user 3910. In some implementations and embodiments, the user may target additional single occupancy vehicles 3969 to destroy along the priced based navigation route.

FIG. 40 illustrates another exemplary network configuration 4000 module of the disclosed method and system which records the vehicle specifications for a given user on the system 4010 in the setting of a mobile computing device. In some implementations and embodiments, the multi layered network node topology of participating, transacting and/or trading transformed toll and congestion capacity or freight capacity units or securities for price based navigation configuration 4000 includes the following elements, or a subset or superset thereof:

exemplary computing device 4010;

exemplary toll and congestion capacity unit model make 4015;

exemplary toll and congestion capacity unit model type 4025;

exemplary toll and congestion capacity unit model year 4035;

exemplary system menu toggle box 4051;

exemplary toll and congestion capacity unit model fuel type 4045;

exemplary toll and congestion capacity unit model make selection box toggle 4020;

exemplary toll and congestion capacity unit model type selection box toggle 4030;

exemplary toll and congestion capacity unit model year selection box toggle 4040;

exemplary toll and congestion capacity unit model fuel type selection box toggle 4050;

In some implementations and embodiments, the disclosed method and system may allow the user to select the model make such as by example an Acura 4020 as a model make 4015. In some implementations and embodiments the user may select an unlimited variety of vehicle types in the method and system not limiting the system to those vehicle make 4015 or model 4025 types in FIG. 40. In some implementations and embodiments, the user may configure the system for the toll and congestion capacity unit specification model year 4035 or the model fuel type 4045 or a plurality of other vehicle specifications for the purpose of recording specification for the priced based navigation system 4010. In some implementations and embodiments, the data transformation of the transformed toll and congestion capacity unit or security links the attributes or supersets or subsets of the model make 4015, model type 4025, model year 4035, model fuel type 4045, or a plurality of other vehicle features to create specification pools as a feature in the data transformations for the transformed toll and congestion capacity units or securities. In some implementations and embodiments, the combinations of similar vehicle model make 4015, model type 4025, model year 4035, model fuel type 4045 and plurality of other vehicle attributes are fungible or substitutable in the method of the transformed toll and congestion capacity unit or security. To avoid confusion, and to provide further example, but not limit by example, bus or subway or train or air or private automobile or other transformed toll and congestion capacity units or securities may be substitutable under broad specifications of the transformed toll and congestion capacity or security pool provided that the broad transformed specifications are met for delivery within the transformed toll and congestion capacity unit or security pool.

FIG. 41 illustrates another exemplary network configuration 4100 module of the disclosed method and system which records the rider or driver toll and congestion capacity unit specification ratings for a given user on the system 4110 in the setting of a mobile computing device. In some implementations and embodiments, the multi layered network node topology of participating, transacting and/or trading toll and congestion capacity or freight capacity for price based navigation configuration 4100 includes the following elements, or a subset or superset thereof:

exemplary menu toggle box 4115;

exemplary rider toll and congestion capacity unit rating category summary 4120;

exemplary rider toll and congestion capacity unit rating summary 4125;

exemplary rider toll and congestion capacity unit rating X logo amount 4126;

exemplary rider toll and congestion capacity unit rating score for navigation route 4130;

exemplary rider toll and congestion capacity unit rating lifetime score 4135;

exemplary rider toll and congestion capacity unit SOV kills 4140;

exemplary rider toll and congestion capacity unit ride count 4145;

exemplary rider toll and congestion capacity unit ride safety score 4146;

exemplary driver toll and congestion capacity unit rating category summary 4150;

exemplary driver toll and congestion capacity unit rating summary 4155;

exemplary driver toll and congestion capacity unit rating X logo amount 4180;

exemplary driver toll and congestion capacity unit rating score for navigation route 4160;

exemplary driver toll and congestion capacity unit rating lifetime score 4165;

exemplary driver toll and congestion capacity unit SOV kills 5,371;

exemplary driver toll and congestion capacity unit ride count 4175;

exemplary driver toll and congestion capacity unit ride safety score 4185;

In some implementations and embodiments the price based navigation system game overlay layer uses a plurality of the aforementioned combinations to account for user actions in the game overlay of the disclosed method and system.

FIG. 42 illustrates another exemplary network configuration 4200 module of the disclosed method and system which records the rider or driver transformed toll and congestion capacity unit or security specification and market framework for the transformation for a specified plurality of routes. In some implementations and embodiments, the multi layered network node topology of participating, transacting and/or trading transformed toll and congestion capacity or freight capacity units or securities for price based navigation configuration 4200 includes the following elements, or a subset or superset thereof:

exemplary computing device to display the method or system 4205;

exemplary estimated time of a primary indexed price based navigation route of a transformed toll and congestion capacity unit or security 4120;

exemplary market price of a buyer and seller of primary price based navigation route of a transformed toll and congestion capacity unit or security 4233;

exemplary price based navigation route of a primary transformed toll and congestion capacity unit or security 4211;

exemplary estimated time of a secondary indexed price based navigation route of a transformed toll and congestion capacity unit or security 4231;

exemplary estimated time of a secondary indexed price based navigation route of a transformed toll and congestion capacity unit or security 4212;

exemplary market price of a buyer and seller of secondary price based navigation route of a transformed toll and congestion capacity unit or security 4230;

exemplary starting point virtual hub of an indexed price based navigation route of a transformed toll and congestion capacity unit or security 4206;

exemplary ending point virtual hub of an indexed price based navigation route of a transformed toll and congestion capacity unit or security 4232;

exemplary ending point and starting point address of virtual hub(s) of an indexed price based navigation route of a transformed toll and congestion capacity unit or security 4213;

exemplary date and time specification of an indexed price based navigation route of a transformed toll and congestion capacity unit or security 4213;

exemplary number or quantity of transformed toll and congestion capacity units or securities that are bidding or buying for purchase by riders of a secondary indexed price based navigation route of a transformed toll and congestion capacity unit or security which is first in the rider queue indexed by highest price 4215;

exemplary price of transformed toll and congestion capacity units or securities that are bidding or buying for purchase by riders of a secondary indexed price based navigation route of a transformed toll and congestion capacity unit or security which is first in the rider queue indexed by highest price 4214;

exemplary price of transformed toll and congestion capacity units or securities that are bidding or buying for purchase by riders of a secondary indexed price based navigation route of a transformed toll and congestion capacity unit or security which is second in the rider queue indexed by second highest price 4216;

exemplary number or quantity of transformed toll and congestion capacity units or securities that are bidding or buying for purchase by riders of a secondary indexed price based navigation route of a transformed toll and congestion capacity unit or security which is second in the rider queue indexed by second highest price 4217;

exemplary number or quantity of transformed toll and congestion capacity units or securities that are offering or selling by drivers of a secondary indexed price based navigation route of a transformed toll and congestion capacity unit or security which is first in the driver queue indexed by lowest price 4226;

exemplary price of transformed toll and congestion capacity units or securities that are offering or selling by drivers of a secondary indexed price based navigation route of a transformed toll and congestion capacity unit or security which is first in the driver queue indexed by lowest price 4228;

exemplary number or quantity of transformed toll and congestion capacity units or securities that are offering or selling by drivers of a secondary indexed price based navigation route of a transformed toll and congestion capacity unit or security which is second in the driver queue indexed by second lowest price 4224;

exemplary price of transformed toll and congestion capacity units or securities that are offering or selling by drivers of a secondary indexed price based navigation route of a transformed toll and congestion capacity unit or security which is second in the driver queue indexed by second lowest price 4225;

exemplary order entry submit button to the method and system for a user order 4218;

exemplary order on the method and system by a driver to sell a specified quantity of transformed toll and congestion capacity units or securities 4223;

exemplary order confirmation on the method and system by a driver sold two units of transformed toll and congestion capacity units or securities 4222;

exemplary market view of priced based navigation layer to display indexed prices of a plurality routes which may be one, two, three, or an infinite number of routes between two virtual hubs 4222;

exemplary game view layer of a transformed toll and congestion capacity unit or security 4220;

exemplary navigation view layer of a transformed toll and congestion capacity unit or security 4219;

In some implementations and embodiments, the disclosed method and system may allow the user to select the model make such as by example an Acura 4020 as a model make 4015 which is placed in a certain transformed toll and congestion capacity specification pool that may be aggregated with similar transformed toll and congestion capacity unit specification participants or units that then display a user 110 selected navigation route 4211 or plurality of routes 4231 and 4211 or an infinite number of routes between the virtual hub start point 4206 and virtual hub endpoint 4232. In some implementations and embodiments the prices 4230 on a route 4231 may display the buy price of the highest bidder or rider on a given route 4231 which is listed in more detail in the rider queue display for highest indexed price bid 4214 for a route 4231. In some implementations and embodiments, the highest bid price 4214 for a rider on a given route 4231 has an associated quantity 4215 of transformed toll and congestion capacity units or securities. Similarly, in some implementations and embodiments, the lowest offer or sale price 4228 for a driver on a given route 4231 has an associated quantity 4226 of transformed toll and congestion capacity units or securities. In some implementations and embodiments, the rider quantity 4215 listed as three units, may be one rider, two riders, or three riders who desire to purchase a given transformed toll and congestion capacity unit(s) or securities so long as the indexed price is queued to the top based on a highest price index and time stamp for a given specification of a transformed toll and congestion capacity unit or security. In some implementations and embodiments, transformed toll and congestion capacity units or securities may represent a similar pool of transformed toll and congestion capacity units or securities based on a superset or subset or the plurality of attributes such as vehicle mode make 4015, vehicle mode model type 4025, vehicle model year 4035, cheapest route 1011, single mode 1012, multi modal 1013, fastest route 1014, most scenic 1015, highest rating 1016, most available 1017, highest volume 1018, most frequent 1019, service level 1020, security and safety 1021, group restricted 1022, modes 810, automobile 811, air 812, autonomous vehicle 813, bike 814, boat 815, bus 816, drone 817, limo 818, motorcycle 819, moped 820, shuttle 821, spaceship 822, subway 823, taxi 824, train 825, fastest optimized 826, cheapest route 827, packages 828, cargo 829, virtual 830, order types 710, 720, term specification 600, timing specification 500, virtual hub end point 230 and start point 220, eScooter, eBike or a plurality of other specifications. In some implementations and embodiments, the match of rider price 4214 and driver price 4228 for a transformed toll and congestion capacity unit(s) or securities occurs the lowest price in the driver queue 4228 equals the highest price in the rider queue 4214. In some implementations and embodiments, if no such match of prices occur between driver and rider queues for a given specification of a transformed toll and congestion capacity unit or security, then prices remain in the queue until a match or a new order entry re-indexes the order of all the deals because the price is higher than the current highest bid in the rider queue 4214 or the queue entries for the transformed toll and congestion capacity unit or security may become re-indexed to place an order with the appropriate price index ranking in a queue that places the highest rider price 4214 in the top and descends by price 4216, then time of order entry all other things equal. In some implementations and embodiments, the driver price queue 4228, 4225 similarly ranks from lowest driver price 4228 at the top of the queue to highest driver price 4228 at the bottom on the queue, then indexing by time subordinate to price for a given pool specification of transformed toll and congestion capacity units or securities. In some implementations and embodiments, a plurality of routes 4231 and 4211 may be displayed as price based navigation options indexed by market pricing. In some implementations and embodiments, the user may select one, two or many, many more routes as to how many they desire to be displayed as options between their virtual hubs to perform calculations that may maximize the number of toll and congestion capacity units or securities they sell on a given route specification or the prices which they obtain or any combination of specifications or objectives the user may have in the price based navigation method and display of transformed toll and congestion capacity unit or security.

FIG. 43 illustrates an exemplary flow chart 4300 of user 110 experience during a transformed toll and congestion capacity unit or security life cycle. In some implementations and embodiments the user 110 may login 4301 to the system which requires the user to go to a plurality of menu options 4302 or user input for origin and destination of virtual toll and congestion capacity hubs 4311 alongside user inputs of time and date 4312 for a given specification that may contain a subset or superset of attributes such as vehicle mode make 4015, vehicle mode model type 4025, vehicle model year 4035, cheapest route 1011, single mode 1012, multi modal 1013, fastest route 1014, most scenic 1015, highest rating 1016, most available 1017, highest volume 1018, most frequent 1019, service level 1020, security and safety 1021, group restricted 1022, modes 810, automobile 811, air 812, autonomous vehicle 813, bike 814, boat 815, bus 816, drone 817, limo 818, motorcycle 819, moped 820, shuttle 821, spaceship 822, subway 823, taxi 824, train 825, fastest optimized 826, cheapest route 827, packages 828, cargo 829, virtual 830, eScooter, eBike, eSkates, eBoards, order types 710, 720, term specification 600, timing specification 500, virtual hub end point 230 and start point 220, or a plurality of other specifications. In some implementations and embodiments, the user may save a route to the “My Routes” 4313 in “Add My Routes” 4314 whereby the user route is saved in the system for one touch retrieval in the future. In some implementations and embodiments, the user may enter a price or quantity to buy or sell a transformed toll and congestion capacity unit or security of a given specification or specification combination 4303 which has many steps involved with the transformation of the toll and congestion capacity unit or security. In some implementations and embodiments, additional data transformations occur to process 4305, market navigation route options and indexing 4305, virtual hub or virtual hub combination data transformations 4305, toll and congestion capacity unit transformations 4305 and many other subsets or supersets of transformed toll and congestion capacity unit combinations and combination specifications 4305. In some implementations and embodiments, if a transformed toll and congestion capacity unit or security matches 4306 in price and specification, then the transformed toll and congestion capacity unit or security moves into delivery 4308 and the deliver process has many steps of electric signal handoff 4308, 4309 and security checks 4308, 4309, 911 system checks 4308, 4309, GPS server and user 110 position checks 4308, 4309 as well as toll and congestion capacity unit rating checks 4308, 4309 and many other possible checks for all the data elements of the transformed toll and congestion capacity unit or security for verification of delivery 4308, 4309. In some implementations and embodiments, if prices of the buyer and seller queue do not match 4307, then the steps of processing 4304, 4305, 4306 repeat until a match is made 4306 to 4308 or an order is cancelled before it expires for the transformed toll and congestion capacity unit or security.

FIG. 44 illustrates an exemplary user interface 4410 for the My Routes Communities functions 4411. In some implementations and embodiments, the user interface 4410 may have a menu option 4451 to move to other areas of the method and system. In some implementations and embodiments, the virtual toll and congestion capacity hub sequence as an object may be meta data tag #PaloSF 4412 to represent Palo Alto, Calif. to San Francisco, Calif. In some implementations and embodiments, #PaloSF 4412 may have an option for the user 110 to Follow or Join or subscribe, or add 4426 the virtual toll and congestion capacity hub sequence #PaloSF 4412. In some implementations and embodiments, the number of followers or network members who are joined to that community object transformed data structure 4412 are 502k 4426. In some implementations and embodiments, the virtual toll and congestion capacity hub sequence as an object may be meta data tag #MenloSF 4413 to represent Menlo Park, Calif. to San Francisco, Calif. In some implementations and embodiments, #MenloSF 4413 may have an option for the user 110 to Follow or Join or subscribe, or add 4427 the virtual toll and congestion capacity hub sequence #MenloSF 4413. In some implementations and embodiments, the number of followers or network members who are joined to that community object transformed data structure 4413 are 100k 4427. In some implementations and embodiments, the virtual toll and congestion capacity hub sequence as an object may be meta data tag #SFSantaCruz 4414 to represent San Francisco, Calif. to Santa Cruz, Calif. In some implementations and embodiments, #SFSantaCruz 4414 may have an option for the user 110 to Follow or Join or subscribe, or add 4428 the virtual toll and congestion capacity hub sequence #SFSantaCruz 4414. In some implementations and embodiments, the number of followers or network members who are joined to that community object transformed data structure 4414 are 42k 4428. In some implementations and embodiments, the virtual toll and congestion capacity hub sequence as an object may be meta data tag #NobHillWharf 4415 to represent Nob Hill San Francisco, Calif. to Fishermans Wharf, San Francisco, Calif. In some implementations and embodiments, #NobHillWharf 4415 may have an option for the user 110 to Follow or Join or subscribe, or add 4429 the virtual toll and congestion capacity hub sequence #NobHillWharf 4415. In some implementations and embodiments, the number of followers or network members who are joined to that community object transformed data structure 4415 are 15k 4429. In some implementations and embodiments, the virtual toll and congestion capacity hub sequence as an object may be meta data tag #CornellWegmans 4416 to represent Cornell University, Ithaca, N.Y. to Wegmans, Ithaca, N.Y. In some implementations and embodiments, #CornellWegmans 4416 may have an option for the user 110 to Follow or Join or subscribe, or add 4430 the virtual toll and congestion capacity hub sequence #CornellWegmans 4416. In some implementations and embodiments, the number of followers or network members who are joined to that community object transformed data structure 4416 are 3k 4430. In some implementations and embodiments, the virtual toll and congestion capacity hub sequence as an object may be meta data tag #ICWegmans 4417 to represent Ithaca College, Ithaca, N.Y. to Wegmans, Ithaca, N.Y. In some implementations and embodiments, #ICWegmans 4417 may have an option for the user 110 to Follow or Join or subscribe, or add 4431 the virtual toll and congestion capacity hub sequence #ICWegmans 4417. In some implementations and embodiments, the number of followers or network members who are joined to that community object transformed data structure 4417 are 1k 4431. In some implementations and embodiments, the virtual toll and congestion capacity hub sequence as an object may be meta data tag #KatyDtownHouston 4418 to represent Katy, Tex. to Houston, Tex. In some implementations and embodiments, #KatyDtownHouston 4418 may have an option for the user 110 to Follow or Join or subscribe, or add 4432 the virtual toll and congestion capacity hub sequence #KatyDtownHouston 4418. In some implementations and embodiments, the number of followers or network members who are joined to that community object transformed data structure 4418 are 380k 4432. In some implementations and embodiments, the virtual toll and congestion capacity hub sequence as an object may be meta data tag #UEastGrandCent 4419 to represent Upper East Side, NYC to Grand Central Station, NYC. In some implementations and embodiments, #UEastGrandCent 4419 may have an option for the user 110 to Follow or Join or subscribe, or add 4433 the virtual toll and congestion capacity hub sequence #UEastGrandCent 4419. In some implementations and embodiments, the number of followers or network members who are joined to that community object transformed data structure 4419 are 400k 4433. In some implementations and embodiments, the virtual toll and congestion capacity hub sequence as an object may be meta data tag #PennStatGrandCent 4420 to represent Penn Station, NYC to Grand Central Station, NYC. In some implementations and embodiments, #PennStatGrandCent 4420 may have an option for the user 110 to Follow or Join or subscribe, or add 4434 the virtual toll and congestion capacity hub sequence #PennStatGrandCent 4420. In some implementations and embodiments, the number of followers or network members who are joined to that community object transformed data structure 4420 are 280k 4434. In some implementations and embodiments, the virtual toll and congestion capacity hub sequence as an object may be meta data tag #IthacaNYC 4421 to represent Ithaca, N.Y. to Grand Central Station, NYC. In some implementations and embodiments, #IthacaNYC 4421 may have an option for the user 110 to Follow or Join or subscribe, or add 4435 the virtual toll and congestion capacity hub sequence #IthacaNYC 4421. In some implementations and embodiments, the number of followers or network members who are joined to that community object transformed data structure 4421 are 19k 4435. In some implementations and embodiments, the virtual toll and congestion capacity hub sequence as an object may be meta data tag #AustinHou 4422 to represent Austin, Tex. to Houston, Tex. In some implementations and embodiments, #AustinHou 4422 may have an option for the user 110 to Follow or Join or subscribe, or add 4436 the virtual toll and congestion capacity hub sequence #AustinHou 4422. In some implementations and embodiments, the number of followers or network members who are joined to that community object transformed data structure 4422 are 100k 4436. In some implementations and embodiments, the virtual toll and congestion capacity hub sequences may be recommended 4423 to follow as an object may be meta data tag #HarvardBCommons 4424 to represent Harvard, Cambridge, Mass. to Boston Commons. In some implementations and embodiments, #HarvardBCommons 4424 may have an option for the user 110 to Follow or Join or subscribe, or add 4437 the virtual toll and congestion capacity hub sequence #HarvardBCommons 4424. In some implementations and embodiments, the number of followers or network members who are joined to that community object transformed data structure 4424 are 89k 4437. In some implementations and embodiments, the virtual toll and congestion capacity hub sequences may be recommended 4423 to follow as an object may be meta data tag #NapervilleChiMkt 4425 to represent Naperville, Chicago to Marketplace, Chicago, Ill. In some implementations and embodiments, #NapervilleChiMkt 4425 may have an option for the user 110 to Follow or Join or subscribe, or add 4438 the virtual toll and congestion capacity hub sequence #NapervilleChiMkt 4425. In some implementations and embodiments, the number of followers or network members who are joined to that community object transformed data structure 4425 are 39k 4438.

FIG. 45 illustrates an exemplary user interface 4500 for the My Routes Communities Group 4515 for a specific transformed data structure of a transformed community virtual hub sequence 4520. In some implementations and embodiments, the meta data virtual hub sequence #PaloSF 4520 may list the long form route details in the about the route section 4522. In some implementations and embodiments, the specific hub sequence #PaloSF 4520 may list the amount of followers and an option to follow 4560. In some implementations and embodiments, the specific hub sequence #PaloSF 4520 may list the ability to share the community group with another social network or text or email or other network protocol. In some implementations and embodiments, the specific hub sequence #PaloSF 4520 may list group as public 4550 or private 4545. In some implementations and embodiments, the specific hub sequence #PaloSF 4520 may list gateway to buy or sell 4540 transformed toll and congestion capacity units using the LOB 300 for a commute community 241. In some implementations and embodiments, the specific hub sequence #PaloSF 4520 may list specific pick up hub address location 4535 or drop off point address 4530. In some implementations and embodiments, the specific hub sequence #PaloSF 4520 may list the activity statistics and data with respect to the number of riders 4525, number of drivers 4525, number of seats 4525, number of trades 4525, frequency of toll and congestion capacity units 4525, volume of toll and congestion capacity units 4525, daily high price for toll and congestion capacity units 4525, daily low price for toll and congestion capacity units on the community object of #PaloSF 4520, yearly high price 4525, yearly low price 4525, news, research, trending, feeds for the #PaloSF 4520 virtual hub sequence.

FIG. 46 illustrates an exemplary user interface 4600 with respect to My Route Sequences 4615 which may transform sequences with more than two virtual hubs into sequences as two or three or more series of route sequences 4620. In some implementations and embodiments, #PaloSF #SFSaus 4620 may represent an origin virtual hub sequence of Palo Alto, Calif. to San Francisco, Calif. followed by a secondary sequence of San Francisco, Calif. to Sausalito, Calif. 4620. Multi leg virtual hub sequences allow for the power of the data transformation to link the villages, cities or states from a network toll and congestion capacity topology structure from multiple providers of toll and congestion capacity units to provide higher levels of frequency and market opportunity to link public and private systems among many other benefits. In some implementations and embodiments, #PaloSF #SFSaus 4620 may allow input from users to join, follow, subscribe or become a member of multi leg sequences which help solve potential last mile issues within toll and congestion capacity systems 4680. In some implementations and embodiments, #IthacaNYC #NYCMid 4625, may allow for a toll and congestion capacity unit seller or buyer to connect two disparate toll and congestion capacity networks to provide last mile toll and congestion capacity to a destination at the lowest market cost because each leg or series of virtual hub sequences has an independent market associated with the leg or virtual hub sequence #IthacaNYC #NYCMid 4625. In some implementations and embodiments, #IthacaNYC #NYCMid 4625 may allow input from users to join, follow, subscribe or become a member of multi leg sequences which help solve potential last mile issues within toll and congestion capacity systems 4675. In some implementations and embodiments, three two leg sequences may be attached through data transformations such that #AustinHou then takes a toll and congestion capacity unit to #HouMem which then takes a toll and congestion capacity unit to #MemVoss. The #AustinHou #HouMem #MemVoss 4635 three leg virtual hub sequence combination may further solve last mile issues for travelers where public transport may be an issue 4665 or private rides simply are going a different direction, but the sequence community object transformation helps travelers understand options and piece multiple toll and congestion capacity systems onto a single community based object to aggregate communication and transaction benefits of the system. In some implementations and embodiments, prior history navigation searches and locations may be used to build recommended additional sequences 4640 which may be recommended for users to subscribe, join, follow or become a member. In some implementations and embodiments, the virtual hub route sequence may link 4 or more virtual hub sequence pairs or even combinations of already linked community object pairs 4645. In some implementations and embodiments, #AustinHou #HouMem #MemVoss #VossBein 4645 may be linked to provide a last mile sequence to a traveler or driver from Austin to the Memorial Area of Houston in a specific address. Traversing a series of linked trips may allow for the cost of non-linked trips to be dramatically lower due to using a series of connected local seats rather than a private for hire vehicle which may be 10 times the cost and add a reverse dead head trip that further pollutes the environment and leaves the driver without additional income on the dead head return leg. The transformed virtual hub sequence methodology allows for toll and congestion capacity systems to be integrated in ways that were not formerly possible because the systems were disparate or simply did not allow for linked trips or linked community objects that could optimize topological network structures over existing inefficient structures. In some implementations and embodiments, virtual hub sequences which have been linked 4645 may also allow users to subscribe 4660. In some implementations and embodiments, #PaloSF #SFSaus #SausMarinTerm 4650 may be linked to provide a last mile sequence to a traveler or driver from Palo Alto, Calif. to Marin Terminal in Sausilito, Calif. in a specific address. In some implementations and embodiments, virtual hub sequences which have been linked 4650 may also allow users to subscribe 4655.

FIG. 47 illustrates an exemplary user menu interface 4700. In some implementations and embodiments, menu options may list as buy/sell/trade 4716 to go to the toll and congestion capacity unit gateway trading platform for virtual hub combinations and virtual hub sequences. In some implementations and embodiments, the user interface may allow a user to go to the navigation 4717 module for price based navigation or route selection based on cost or earnings from a route as described in U.S. patent application Ser. No. 16/242,967, “Price Based Navigation,” filed Jan. 8, 2019; the entirety of which is incorporated by reference herein. Furthermore, as described in U.S. patent application Publication, Ser. No. 15/877,393, “Electronic Forward market exchange for toll and congestion capacity seats and capacity in toll and congestion capacity spaces and vehicles,” filed Jan. 23, 2018, the entirety of which is incorporated by reference herein. In some implementations and embodiments, a user 110 may select my routes 4718 to toggle to routes that are important to their user profile or needs in the network member database 222. In some implementations and embodiments, trips 4719 may be selected to toggle to the trip delivery view. In some implementations and embodiments, orders 4720 may be selected to toggle to cancel or adjust orders in the system that are unfilled. In some implementations and embodiments, users may toggle to the account 4721 page or communities object page 4400 or the route sequences page 4723. In some implementations and embodiments, users 110 may add additional hubs 4724 or may toggle to the gaming interface 3700. In some implementations and embodiments, freight toll and congestion capacity units may need to be scanned on the freight scanning module 4726. In some implementations and embodiments, users may select the reward program module 4727 or the dashboard module 4728. In some implementations and embodiments, the user may select the music 4729 or shopping module 4730. In some implementations and embodiments, the user may select help 4731 or settings 4732 to update account information or privacy settings. In some implementations and embodiments, users 110 may invite friends 4733 for rewards or bonuses or cash or credits 4733. In some implementations and embodiments, users may also logout 4734.

FIG. 48 illustrates an exemplary preamble formula structure 4800 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, the disclosed method and system relates to the sale and purchase or resale or repurchase or transfer and assignment of those certain transportation and freight capacity units. In some implementations and embodiments, SeatsX may relate to the purchase or sale or repurchase and resale of transportation capacity units. In some implementations and embodiments ShipsX may relate to the purchase or sale or repurchase and resale of freight capacity units. In some implementations and embodiments, a SeatsX or ShipsX Trade Hub is synonymous with a Virtual Hub.

FIG. 49 illustrates an exemplary preamble formula extension structure 4900 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, the disclosed method and system relates to the sale and purchase or resale or repurchase or transfer and assignment of those certain transportation and freight capacity units. In some implementations and embodiments, SeatsX may relate to the purchase or sale or repurchase and resale of transportation capacity units. In some implementations and embodiments, ShipsX may relate to the purchase or sale or repurchase and resale of freight capacity units. In some embodiments and implementations, CirclesX, may relate to the purchase and sale of any generalized geolocation exchange unit. In some implementations and embodiments, a SeatsX or ShipsX or CirclesX Trade Hub is synonymous with a Virtual Hub.

FIG. 50 illustrates an exemplary definition formula structure 5000 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of definitions are set from a superset or subset or combination of the following structure to include Affiliate, Agreement, Applicable Interest Rate, Assigning Party, Bankrupt entity and other terms in accordance with some embodiments. In some implementations and embodiments, the formula for the transformed transportation or freight capacity unit may be present within the definitions stated in FIG. 50.

FIG. 51 illustrates an exemplary definition formula structure 5100 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of definitions are set from a superset or subset or combination of the following structure to include Business Day, Buyer, Claiming Party, Claims, Confirmation, Contract Price, Contract Value, Contractual Currency and other terms in accordance with some embodiments. In some implementations and embodiments, the formula for the transformed transportation or freight capacity unit may be present within the definitions stated in FIG. 51.

FIG. 52 illustrates an exemplary definition formula structure 5200 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of definitions are set from a superset or subset or combination of the following structure to include Cost, Defaulting Party, Default Rate, Delivery, Early Termination Date, Effective Date, Event of Default, Force Majeure and other terms in accordance with some embodiments. In some implementations and embodiments, the formula for the transformed transportation or freight capacity unit may be present within the definitions stated in FIG. 52.

FIG. 53 illustrates an exemplary definition formula structure 5300 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of definitions are set from a superset or subset or combination of the following structure to include GTCs, Independent Amount, Letters of Credit, Margin Party, Non-Defaulting Party, Option, Option Buyer, Option Seller, Party or Parties, Party B, Payment Date, Performance Assurance and other terms in accordance with some embodiments. In some implementations and embodiments, the formula for the transformed transportation or freight capacity unit may be present within the definitions stated in FIG. 53.

FIG. 54 illustrates an exemplary definition formula structure 5400 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of definitions are set from a superset or subset or combination of the following structure to include Person, Premium, Present Value Discount Rate, Ask Yield, Product, Recording, Replacement Value, Seller, Settlement Amount, and other terms in accordance with some embodiments. In some implementations and embodiments, the formula for the transformed transportation or freight capacity unit may be present within the definitions stated in FIG. 54.

FIG. 55 illustrates an exemplary definition formula structure 5500 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of definitions are set from a superset or subset or combination of the following structure to include Taxes, Term, Terminated Transaction, Termination Payment, Termination Replacement Price, Termination Replacement Transaction and other terms in accordance with some embodiments. In some implementations and embodiments, the formula for the transformed transportation or freight capacity unit may be present within the definitions stated in FIG. 55.

FIG. 56 illustrates an exemplary definition formula structure 5600 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of definitions are set from a superset or subset or combination of the following structure to include Trade Date, Transaction, Transportation Capacity Unit and Freight Capacity Unit may be used interchangeably and other terms in accordance with some embodiments. In some implementations and embodiments, the formula for the transformed transportation or freight capacity unit may be present within the definitions stated in FIG. 56.

FIG. 57 illustrates an exemplary definition formula structure 5700 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of definitions are set from a superset or subset or combination of the following structure to include Confirmation and other terms in accordance with some embodiments. In some implementations and embodiments, a plurality of definitions are set from a superset or subset or combination of the following structure to include Recording of Transactions and other terms in accordance with some embodiments. In some implementations and embodiments, the formula for the transformed transportation or freight capacity unit may be present within the definitions stated in FIG. 57.

FIG. 58 illustrates an exemplary definition formula structure 5800 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of definitions are set from a superset or subset or combination of the following structure to include Inconsistency with these established formulas for a plurality of transformed transportation unit formulas. In some implementations and embodiments, the formula for the transformed transportation or freight capacity unit may be present within the definitions stated in FIG. 58.

FIG. 59 illustrates an exemplary definition formula structure 5900 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of definitions are set from a superset or subset or combination of the following structure to include Force Majeure with these established formulas for a plurality of transformed transportation unit formulas. In some implementations and embodiments, Force Majeure may occur and be written in one or more business days from the Force Majeure event. In some implementations and embodiments, Remedies for Product Delivery Failures may be caused by failure of failure of the Buyer or Seller to delivery the TCU and the non-failing party shall be entitled to the formula of the then current price of such TCI as liquidated damages. In some implementations and embodiments, the formula for the transformed transportation or freight capacity unit may be present within the definitions stated in FIG. 59.

FIG. 60 illustrates an exemplary definition formula structure 6000 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of definitions are set from a superset or subset or combination of the following structure to include events of default and remedies with these established formulas for a plurality of transformed transportation and freight unit formulas. In some implementations and embodiments, the formula for the transformed transportation or freight capacity unit may be present within the definitions stated in FIG. 60. In some implementations and embodiments, events of default may include failure to make payment when required, making false representations, failure to perform to deliver the TCU, post-merger or reorganization failing to support the obligations of TCU transactions. In some implementations and embodiments, events of default may include credit default or failure to delivery performance assurance or margin.

FIG. 61 illustrates an exemplary definition formula structure 6100 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of definitions are set from a superset or subset or combination of the following structure to include effect of default for a plurality of transformed transportation unit formulas. In some implementations and embodiments, effect of default may occur and be written in one or more business days from the Effect of an event of Default. In some implementations and embodiments, the calculation of a termination payment may be “Settlement Amount” for such Terminated Transaction shall be the difference between the Replacement Value and the Contract Value of such Terminated Transaction, as calculated by the Non-Defaulting Party as follows:

i. If the Non-Defaulting Party in respect of a Terminated Transaction is Seller and the Replacement Value is greater than the Contract Value, then the Settlement Amount shall be the amount of such excess plus the pro rata portion of the Contract Value attributable to any Contract Price actually paid by Buyer and shall be payable by the Non-Defaulting Party to the Defaulting Party;

ii. If the Non-Defaulting Party in respect of a Terminated Transaction is Seller and the Replacement Value is less than the Contract Value, then the Settlement Amount shall be the amount of such difference less the pro rata portion of the Contract Value attributable to any Contract Price actually paid by Buyer and shall be payable by the Defaulting Party to the Non-Defaulting Party. In some implementations and embodiments, the formula for the transformed transportation or freight capacity unit may be present within the definitions stated in FIG. 61.

FIG. 62 illustrates an exemplary definition formula structure 6200 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of definitions are set from a superset or subset or combination of the following structure to include effect of default for a plurality of transformed transportation unit formulas. In some implementations and embodiments, effect of default may occur and be written in one or more business days from the Effect of an event of Default. In some implementations and embodiments, the calculation of a termination payment may be “Settlement Amount” for such Terminated Transaction shall be the difference between the Replacement Value and the Contract Value of such Terminated Transaction, as calculated by the Non-Defaulting Party as follows:

iii. If the Non-Defaulting Party in respect of a Terminated Transaction is Buyer and the Replacement Value is greater than the Contract Value, then the Settlement Amount shall be the amount of such excess plus the pro rata portion of the Contract Value attributable to any Contract Price actually paid by Buyer and shall be payable by the Defaulting Party to the Non-Defaulting Party; and

iv. If the Non-Defaulting Party in respect of a Terminated Transaction is Buyer and the Replacement Value is less than the Contract Value, then the Settlement Amount shall be the amount of such difference less the pro rata portion of the Contract Value attributable to any Contract Price actually paid by Buyer and shall be payable by the Non-Defaulting Party to the Defaulting Party.

v. If the sum of the Settlement Amounts payable by the Defaulting Party is greater than the sum of Settlement Amounts payable by the Non-Defaulting Party, then a single payment in the amount of such excess will be payable to the Non-Defaulting Party by the Defaulting Party on the date specified in Section 5.4. If the sum of the Settlement Amounts payable by the Non-Defaulting Party is greater than the sum of the Settlement Amounts payable by the Defaulting Party, then a single payment in the amount of such excess Settlement Amounts will be payable by the Non-Defaulting Party to the Defaulting Party on the date specified in Section 5.4. In some implementations and embodiments, the formula for the transformed transportation or freight capacity unit may be present within the definitions stated in FIG. 62.

FIG. 63 illustrates an exemplary definition formula structure 6300 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of definitions are set from a superset or subset or combination of the following structure to include Notice of Payment of Termination Payment of transformed transportation unit formulas. In some implementations and embodiments, Notice of Payment of Termination Payment may occur and be written in one or more business days from the Notice of Payment of Termination Payment. In some implementations and embodiments, As soon as practicable after the calculation of the Termination Payment, the Non-Defaulting Party shall notify the Defaulting Party in writing of the amount of the Termination Payment and whether the Termination Payment is due to or due from the Non-Defaulting Party. The notice shall include a written statement explaining in reasonable detail the calculation of such Termination Payment to the Defaulting Party and SeatsX. If the Termination Payment is due to the Non-Defaulting Party, the Defaulting Party shall pay such Termination Payment within five (5) Business Days after receipt of such notice, together with interest thereon (before as well as after judgment) at the Default Rate, to the extent permitted under applicable law, compounded daily, from (and including) the Early Termination Date to (but excluding) the day such amount is paid; provided, however, that to the extent that the Termination Payment is calculated in respect of a termination pursuant to Article 3 5900, no such interest shall be payable. If the Termination Payment is due from the Non-Defaulting Party, the Non-Defaulting Party shall pay such Termination Payment, without interest, within twenty (20) Business Days after delivery of such notice.

FIG. 64 illustrates an exemplary definition formula structure 6400 for a transformed Transportation or Freight Capacity Unit. In some implementations and embodiments, a plurality of definitions are set from a superset or subset or combination of the following structure to include Notice of Payment of Termination Payment of transformed transportation unit formulas. In some implementations and embodiments, Notice of Payment of Termination Payment may occur and be written in one or more business days from the Notice of Payment of Termination Payment. In some implementations and embodiments, As soon as practicable after the calculation of the Termination Payment, the Non-Defaulting Party shall notify the Defaulting Party in writing of the amount of the Termination Payment and whether the Termination Payment is due to or due from the Non-Defaulting Party. The notice shall include a written statement explaining in reasonable detail the calculation of such Termination Payment to the Defaulting Party and SeatsX. If the Termination Payment is due to the Non-Defaulting Party, the Defaulting Party shall pay such Termination Payment within five (5) Business Days after receipt of such notice, together with interest thereon (before as well as after judgment) at the Default Rate, to the extent permitted under applicable law, compounded daily, from (and including) the Early Termination Date to (but excluding) the day such amount is paid; provided, however, that to the extent that the Termination Payment is calculated in respect of a termination pursuant to Article 3 5900, no such interest shall be payable. If the Termination Payment is due from the Non-Defaulting Party, the Non-Defaulting Party shall pay such Termination Payment, without interest, within twenty (20) Business Days after delivery of such notice.

FIG. 65 illustrates an exemplary definition formula structure 6500 for a transformed Transportation or Freight Capacity Unit. In some implementations and embodiments, a plurality of definitions are set from a superset or subset or combination of the following structure to include Closeout Setoff features 6500. After calculation of a Termination Payment in accordance with Section 5.3 (unless such Termination Payment was calculated as a result of a termination pursuant to Article 3), if the Defaulting Party would be owed the Termination Payment, the Non-Defaulting Party shall be entitled, at its option and in its discretion, to set off against such Termination Payment any amounts due and owing by the Defaulting Party to the Non-Defaulting Party under any other agreements, instruments or undertakings between the Defaulting Party and the Non-Defaulting Party which are not related to the SeatsX Trade Hub. The remedy provided for in this Section shall be without prejudice and in addition to any right of setoff, combination of accounts, lien or other right to which any Party is at any time otherwise entitled (whether by operation of law, contract or otherwise). Notwithstanding the foregoing, the Non-Defaulting Party shall not be required to pay to the Defaulting Party any amount owing by the Non-Defaulting Party under this Agreement until the Non-Defaulting Party receives confirmation satisfactory to it in its reasonable discretion that all obligations of the Defaulting Party to make any payments of any kind whatsoever to the Non-Defaulting Party or any of its Affiliates or otherwise which are due and payable as of the Early Termination Date have been fully and finally paid in cash In some implementations and embodiments.

FIG. 66 illustrates an exemplary definition formula structure 6600 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of definitions are set from a superset or subset or combination of the following structure to include Disputes of Invoices and Payments of transformed transportation unit formulas. In some implementations and embodiments, a plurality of limitation of remedies, liability and damages are set from a superset or subset or combination of the following structure to include limitation of remedies, liability and damages of transformed transportation unit formulas. In some implementations and embodiments, remedies are limited to the formulas of Replacement Value and Contract Value structured in 6100 and 6200.

FIG. 67 illustrates an exemplary definition formula structure 6700 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of limitation of remedies, liability and damages are set from a superset or subset or combination of the following structure to include limitation of remedies, liability and damages of transformed transportation unit formulas. In some implementations and embodiments, remedies are limited to the formulas of Replacement Value and Contract Value structured in 6100 and 6200.

FIG. 68 illustrates an exemplary definition formula structure 6800 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of limitation of remedies, liability and damages are set from a superset or subset or combination of the following structure to include limitation of remedies, liability and damages of transformed transportation unit formulas. In some implementations and embodiments, remedies are limited to the formulas of Replacement Value and Contract Value structured in 6100 and 6200. In some implementations and embodiments, financial information may be requested to satisfy performance assurance 5300 formulas for credit support 6900 of Transportation and Freight Capacity Units.

FIG. 69 illustrates an exemplary definition formula structure 6900 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of credit support formulas are set from a superset or subset or combination of the following structure to include credit protection in the form of performance assurance and grants of security interest and remedies of transformed transportation unit formulas. In some implementations and embodiments, credit support may follow the formulas in the definition of performance assurance 5300. In some implementations and embodiments, credit support and performance assurance calculations may include value at risk calculations that consider duration of the contract, price volatility formulas, price correlation formulas, closeout setoff formulas, cross-default formulas and other formulas that may consider the value and credit fluctuations of the credit worthiness of a counterparty and the market value and Replacement Value of such contracts of transformed transportation and freight capacity units.

FIG. 70 illustrates an exemplary definition formula structure 7000 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of general formulas are set from a superset or subset or combination of the following structure to include additional formulas of transformed transportation unit formulas. In some implementations and embodiments, general formulas may follow the formulas in the definition of performance assurance 5300, representation and warranties formulas to determine the variance of financial results of a counterparty to quantify a truthfulness score. In some implementations and embodiments, a credit score or truthfulness score may use earnings manipulation formulas that seek variance thresholds on cash flow, inventories, receivables, payables, goodwill, and other accounting standards that may be placed in a model to determine the general variability of the credit worthiness of the counterparty.

FIG. 71 illustrates an exemplary definition formula structure 7100 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of general formulas are set from a superset or subset or combination of the following structure to include additional formulas of transformed transportation unit formulas. In some implementations and embodiments, these formulas may include cross checks on criminal background, driver license scores, indemnification scores, or scores to determine the likelihood of litigious actions.

FIG. 72 illustrates an exemplary definition formula structure 7200 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of general formulas are set from a superset or subset or combination of the following structure to include additional formulas of transformed transportation unit formulas. In some implementations and embodiments, these formulas may include credit support for successors and assignments to provide scores of the likelihood a counterparty assuming the transportation or freight capacity unit may handle the credit obligations without triggering an event of default.

FIG. 73 illustrates an exemplary definition formula structure 7300 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of general formulas are set from a superset or subset or combination of the following structure to include additional formulas of transformed transportation unit formulas. In some implementations and embodiments, these formulas may include dispute resolution formulas and threshold formulas to methodically evaluate and settle dispute amounts.

FIG. 74 illustrates an exemplary definition formula structure 7400 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of general formulas are set from a superset or subset or combination of the following structure to include additional formulas of transformed transportation unit formulas. In some implementations and embodiments, these formulas may include dispute resolution formulas and threshold formulas to methodically evaluate and settle dispute amounts and arbitration awards.

FIG. 75 illustrates an exemplary definition formula structure 7500 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of general formulas are set from a superset or subset or combination of the following structure to include additional formulas of transformed transportation unit formulas. In some implementations and embodiments, these formulas may include dispute resolution formulas and threshold formulas to methodically evaluate and settle dispute amounts and arbitration awards.

FIG. 76 illustrates an exemplary definition formula structure 7600 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of general formulas are set from a superset or subset or combination of the following structure to include additional formulas of transformed transportation unit formulas. In some implementations and embodiments, these formulas may include dispute resolution formulas and threshold formulas to methodically evaluate and settle dispute amounts and arbitration awards.

FIG. 77 illustrates an exemplary definition formula structure 7700 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of general formulas are set from a superset or subset or combination of the following structure to include additional formulas of transformed transportation unit formulas. In some implementations and embodiments, these formulas may include notice formulas and threshold formulas to methodically evaluate and settle dispute amounts and arbitration awards and counterparty information updates.

FIG. 78 illustrates an exemplary definition formula structure 7800 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of general formulas are set from a superset or subset or combination of the following structure to include additional formulas of transformed transportation unit formulas. In some implementations and embodiments, these formulas may include notice formulas and threshold formulas to methodically evaluate and settle severability and intent and regulation and exchange rule.

FIG. 79 illustrates an exemplary definition formula structure 7900 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of general formulas are set from a superset or subset or combination of the following structure to include additional formulas of transformed transportation unit formulas. In some implementations and embodiments, these formulas may include termination, liquidation, net out, offset, and plurality of counterpart formulas and threshold formulas to methodically evaluate and settle termination, liquidation, net out, offset, and plurality of counterpart formulas.

FIG. 80 illustrates an exemplary notice of correspondence 8000 for a transformed Transportation or Freight Capacity Unit which is interchangeable with a toll and congestion capacity unit or sidewalk capacity unit or toll congestion capacity unit. In some implementations and embodiments, a plurality of general formulas are set from a superset or subset or combination of the following structure to include additional notice of correspondence.

FIG. 81 illustrates an exemplary notice step flowchart and application of one or more transportation for freight capacity unit transformations 8100. In some implementations and embodiments, at a computing device with a touchscreen interface, audio interface, augmented reality interface, mixed reality interface, brain wave interface, visual interface, detect a transportation or freight capacity unit 8102, the method and system may apply one or more transportation or freight capacity unit transformations to create a new transportation or freight capacity unit 8103. In some implementations and embodiments, the transformation may include the following transformations of the transportation and freight capacity unit or a superset or subset thereof:

-   -   i) apply an interest rate to discount forward transportation or         freight capacity units 8104;     -   ii) apply a contract price to the forward transportation or         freight capacity units 8105;     -   iii) apply a default interest rate to the forward transportation         or freight capacity units 8106;     -   iv) apply an early termination date to the forward         transportation or freight capacity units 8107;     -   v) apply a force majeure event for forward transportation or         freight capacity units 8108;     -   vi) apply a letter of credit or performance assurance for         forward transportation or freight capacity units 8109;     -   vii) apply a termination replacement price meaning with respect         to a Termination Replacement Transaction, the price which the         Non-Defaulting Party acting in a commercially reasonable manner,         pays or receives or could pay or receive in connection with the         Termination Replacement Transaction (plus Costs reasonably         incurred by the Non-Defaulting Party in entering into the         Termination Replacement Transaction) for forward transportation         or freight capacity units 8110.         In some implementations and embodiments, the aforementioned         steps and transformations may be processed to transform the toll         capacity unit 8111.

FIG. 82 illustrates an exemplary notice step flowchart and application of one or more toll capacity unit transformations 8200. In some implementations and embodiments, at a computing device with a touchscreen interface, audio interface, augmented reality interface, mixed reality interface, brain wave interface, visual interface, detect a transportation or freight capacity unit 8202, the method and system may apply one or more toll capacity unit transformations to create a new transportation or freight capacity unit 8203. In some implementations and embodiments, the transformation may include the following transformations of the toll capacity unit or a superset or subset thereof:

-   -   i) apply a Termination Replacement Transaction 8204 meaning a         transaction for the purchase or sale, as applicable, of a         Product(s) for any remaining period or part thereof to be         purchased or sold in connection with the Terminated Transaction,         provided that, the transaction replacing any Terminated         Transaction or portion thereof shall be deemed to have a term:         -   (1) commencing on the Early Termination Date; and         -   (2) ending on the last day of the term for forward toll             capacity units;     -   ii) apply a trade confirmation for forward toll capacity units         8205;     -   iii) apply a recorded confirmation for forward toll capacity         units 8206;     -   iv) apply remedies for product delivery failures for forward         toll capacity units as liquidated damages 8207;     -   v) apply events of default for forward toll capacity units as         liquidated damages 8208;         In some implementations and embodiments, the aforementioned         steps and transformations may be processed to transform the toll         capacity unit 8209.

FIG. 83 illustrates an exemplary notice step flowchart and application of one or more toll capacity unit transformations 8300. In some implementations and embodiments, at a computing device with a touchscreen interface, audio interface, augmented reality interface, mixed reality interface, brain wave interface, visual interface, detect a toll capacity unit 8302, the method and system may apply one or more toll capacity unit transformations to create a new transportation or freight capacity unit 8303. In some implementations and embodiments, the transformation may include the following transformations of the toll capacity unit or a superset or subset thereof:

-   -   i) Apply a Calculation of a Termination Payment 8304.         -   a. If an Early Termination Date is designated with respect             to any Transaction, the “Settlement Amount” for such             Terminated Transaction shall be the difference between the             Replacement Value and the Contract Value of such Terminated             Transaction, as calculated by the Non-Defaulting Party as             follows:         -   (1) If the Non-Defaulting Party in respect of a Terminated             Transaction is Seller and the Replacement Value is greater             than the Contract Value, then the Settlement Amount shall be             the amount of such excess plus the pro rata portion of the             Contract Value attributable to any Contract Price actually             paid by Buyer and shall be payable by the Non-Defaulting             Party to the Defaulting Party;         -   (2) If the Non-Defaulting Party in respect of a Terminated             Transaction is Seller and the Replacement Value is less than             the Contract Value, then the Settlement Amount shall be the             amount of such difference less the pro rata portion of the             Contract Value attributable to any Contract Price actually             paid by Buyer and shall be payable by the Defaulting Party             to the Non-Defaulting Party;     -   for forward toll capacity units.         In some implementations and embodiments, the aforementioned         steps and transformations may be processed to transform the toll         capacity unit 8305.

FIG. 84 illustrates an exemplary notice step flowchart and application of one or more toll capacity unit transformations 8400. In some implementations and embodiments, at a computing device with a touchscreen interface, audio interface, augmented reality interface, mixed reality interface, brain wave interface, visual interface, detect a transportation or freight capacity unit 8402, the method and system may apply one or more toll capacity unit transformations to create a new toll capacity unit 8403. In some implementations and embodiments, the transformation may include the following transformations of the toll capacity unit or a superset or subset thereof:

-   -   i) apply a Calculation of a Termination Payment 8404;         -   (1) If the Non-Defaulting Party in respect of a Terminated             Transaction is Buyer and the Replacement Value is greater             than the Contract Value, then the Settlement Amount shall be             the amount of such excess plus the pro rata portion of the             Contract Value attributable to any Contract Price actually             paid by Buyer and shall be payable by the Defaulting Party             to the Non-Defaulting Party; and         -   (2) If the Non-Defaulting Party in respect of a Terminated             Transaction is Buyer and the Replacement Value is less than             the Contract Value, then the Settlement Amount shall be the             amount of such difference less the pro rata portion of the             Contract Value attributable to any Contract Price actually             paid by Buyer and shall be payable by the Non-Defaulting             Party to the Defaulting Party.         -   (3) If the sum of the Settlement Amounts payable by the             Defaulting Party is greater than the sum of Settlement             Amounts payable by the Non-Defaulting Party, then a single             payment in the amount of such excess will be payable to the             Non-Defaulting Party by the Defaulting Party on the date             specified in Section 5.4 6400. If the sum of the Settlement             Amounts payable by the Non-Defaulting Party is greater than             the sum of the Settlement Amounts payable by the Defaulting             Party, then a single payment in the amount of such excess             Settlement Amounts will be payable by the Non-Defaulting             Party to the Defaulting Party on the date specified in             Section for forward toll capacity units.

In some implementations and embodiments, the aforementioned steps and transformations may be processed to transform the toll capacity unit 8405.

FIG. 85 illustrates a block diagram of a hardware configuration 8500 in which one or more various technologies described herein may be incorporated and practiced. The hardware configuration 8500 can be used to implement the computing systems discussed above (e.g., the computing devices mentioned above). The hardware configuration 8500 can include a processor 8510, a memory 8520, a storage device 8530, and an input/output device 8540. Each of the components 8510, 8520, 8530, and 8540 can, for example, be interconnected using a system bus 8550. The processor 8510 can be capable of processing instructions for execution within the hardware configuration 8500. In one implementation, the processor 8510 can be a single-threaded processor. In another implementation, the processor 8510 can be a multi-threaded processor. The processor 8510 can be capable of processing instructions stored in the memory 8520 or on the storage device 8530.

The memory 8520 can store information within the hardware configuration 5300. In one implementation, the memory 8520 can be a computer-readable medium. In one implementation, the memory 8520 can be a volatile memory unit. In another implementation, the memory 8520 can be a non-volatile memory unit.

In some implementations, the storage device 8530 can be capable of providing mass storage for the hardware configuration 8500. In one implementation, the storage device 8530 can be a computer-readable medium. In various different implementations, the storage device 8530 can, for example, include a hard disk device/drive, an optical disk device, flash memory or some other large capacity storage device. In other implementations, the storage device 8530 can be a device external to the hardware configuration 8500. Various implementations for the memory 8520 and/or the storage device 8530 are further discussed below.

The input/output device 8540 can provide input/output operations for the hardware configuration 8500. In one implementation, the input/output device 8540 can include one or more display system interfaces, sensors and/or data transfer ports.

The subject matter of this disclosure, and/or components thereof, can be realized by instructions that upon execution cause one or more processing devices to carry out the processes and functions described above. Such instructions can, for example, comprise interpreted instructions, such as script instructions, e.g., JavaScript or ECMAScript instructions, or executable code, or other instructions stored in a computer readable medium.

Implementations of the subject matter and the functional operations described in this specification can be provided in digital electronic circuitry, or in computer software, firmware, or hardware, including the structures disclosed in this specification and their structural equivalents, or in combinations of one or more of them. Embodiments of the subject matter described in this specification can be implemented as one or more computer program products, i.e., one or more modules of computer program instructions encoded on a tangible program carrier for execution by, or to control the operation of, data processing apparatus.

A computer program (also known as a program, software, software application, script, or code) can be written in any form of programming language, including compiled or interpreted languages, or declarative or procedural languages, and it can be deployed in any form, including as a stand-alone program or as a module, component, subroutine, or other unit suitable for use in a computing environment. A computer program does not necessarily correspond to a file in a file system. A program can be stored in a portion of a file that holds other programs or data (e.g., one or more scripts stored in a markup language document), in a single file dedicated to the program in question, or in multiple coordinated files (e.g., files that store one or more modules, sub programs, or portions of code). A computer program can be deployed to be executed on one computer or on multiple computers that are located at one site or distributed across multiple sites and interconnected by a communication network.

The processes and logic flows described in this specification can be performed by one or more programmable processors executing one or more computer programs to perform functions by operating on input data and generating output thereby tying the process to a particular machine, e.g., a machine programmed to perform the processes described herein. The processes and logic flows can also be performed by, and apparatus can also be implemented as, special purpose logic circuitry, e.g., an FPGA (field programmable gate array) or an ASIC (application specific integrated circuit).

Computer readable media (e.g., memory 8520 and/or the storage device 8530) suitable for storing computer program instructions and data may include all forms of non-volatile memory, media, and memory devices, including, by way of example, any semiconductor memory devices (e.g., EPROM, EEPROM, solid state memory devices, and flash memory devices); any magnetic disks (e.g., internal hard disks or removable disks); any magneto optical disks; and any CD-ROM and DVD-ROM disks. The processor and the memory can be supplemented by, or incorporated in, special purpose logic circuitry.

The aforementioned description, for purpose of explanation, has been described with reference to specific embodiments. However, the illustrative discussions above are not intended to be exhaustive or to limit the invention to the precise forms disclosed. Many modifications and variations are possible in view of the above teachings. The embodiments were chosen and described in order to best explain the principles of the invention and its practical applications, to thereby enable others skilled in the art to best utilize the invention and various embodiments with various modifications as are suited to the particular use contemplated. 

What is claimed is:
 1. A method, comprising: receiving origin location data and destination location data from a first user, wherein the origin location data corresponds to a geographic origin and the destination location data corresponds to a geographic destination; generating a plurality of routes based on the origin location data and the destination location data; determining a plurality of virtual hubs along the plurality of routes, wherein the plurality of virtual hubs comprises a first virtual hub based on the origin location data and a second virtual hub based on the destination location data; receiving travel cost data for the plurality of routes for one or more geolocation exchange units, wherein the one or more geolocation exchange units corresponds to a predetermined space traveling from the first virtual hub to the second virtual hub, and wherein the travel cost data comprises data relating to tolling over road space, air space, shipping space, waterborne space, parking, curb capacity, sidewalk capacity, travel time, travel expenses, or combinations thereof; receiving market depth data for a geolocation exchange for the one or more geolocation exchange units based on the plurality of routes, wherein the market depth data comprises one or more bid prices and one or more offer prices for the one or more geolocation exchange units; and selecting an optimized route of the plurality of routes for the one or more geolocation exchange units based on an objective function, wherein the objective function uses the travel cost data, the market depth data, or combinations thereof.
 2. The method of claim 1, wherein the objective function comprises a function configured to minimize travel time, travel expenses, cost of bid prices, tolling over road space, air space, shipping space, waterborne space, parking, curb capacity, sidewalk capacity or combinations thereof.
 3. The method of claim 1, wherein the optimized route comprises a route for travel for the one or more geolocation exchange units using one or more transportation vehicles, wherein the one or more transportation vehicles comprise an automobile, an aircraft, an autonomous vehicle, a motorcycle, a bicycle, a boat, a bus, a subway car, a taxicab, a drone, an unmanned aircraft, a train, or a delivery vehicle.
 4. The method of claim 1, wherein the predetermined space comprises a parking, curb or sidewalk capacity in one or more areas traveling from the first virtual hub to the second virtual hub.
 5. The method of claim 1, further comprising generating a forward commodity contract based on the selected optimized route, wherein the forward commodity contract is for physical delivery of the one or more geolocation exchange units.
 6. The method of claim 1, further comprising receiving constraint data from the first user, wherein the constraint data indicates a selection by the first user of one or more conditions for traveling along the plurality of routes.
 7. The method of claim 6, further comprising: receiving the travel cost data for the plurality of routes based on the constraint data; and receiving the market depth data based on the plurality of routes and the constraint data.
 8. The method of claim 6, wherein the one or more conditions comprise cheapest route, single mode of transportation, multiple modes of transportation, fastest route, most scenic route, highest rated route, most available route, highest volume of participants for route, most frequent route, service level for route, highest safety and security level for route, gender of driver, security of driver, and rating of driver.
 9. A computing system, comprising: one or more processors; and one or more memory comprising program instructions executable by the one or more processors to: receive origin location data and destination location data from a first user, wherein the origin location data corresponds to a geographic origin and the destination location data corresponds to a geographic destination; generate a plurality of routes based on the origin location data and the destination location data; determine a plurality of virtual hubs along the plurality of routes, wherein the plurality of virtual hubs comprises a first virtual hub based on the origin location data and a second virtual hub based on the destination location data; receive travel cost data for the plurality of routes for one or more geolocation exchange units, wherein the one or more geolocation exchange units corresponds to a predetermined space traveling from the first virtual hub to the second virtual hub, and wherein the travel cost data comprises data relating to tolling over road space, air space, shipping space, waterborne space, parking, curb capacity, sidewalk capacity, travel time, travel expenses, or combinations thereof; receive market depth data for a geolocation exchange for the one or more geolocation exchange units based on the plurality of routes, wherein the market depth data comprises one or more bid prices and one or more offer prices for the one or more geolocation exchange units; and select an optimized route of the plurality of routes for the one or more geolocation exchange units based on an objective function, wherein the objective function uses the travel cost data, the market depth data, or combinations thereof.
 10. The computing system of claim 9, wherein the objective function comprises a function configured to minimize tolling over road space, air space, shipping space, waterborne space, travel time, parking, curb capacity, sidewalk capacity, travel expenses, cost of bid prices, or combinations thereof.
 11. The computing system of claim 9, wherein the optimized route comprises a route for travel for the one or more geolocation exchange units using one or more transportation vehicles, wherein the one or more transportation vehicles comprise an automobile, an aircraft, an autonomous vehicle, a motorcycle, a bicycle, a boat, a bus, a subway car, a drone, an unmanned aircraft, a taxicab, a train, or a delivery vehicle.
 12. The computing system of claim 9, wherein the predetermined space comprises a seat or cargo capacity in one or more vehicles traveling from the first virtual hub to the second virtual hub.
 13. The computing system of claim 9, wherein the program instructions further comprise program instructions executable by the one or more processors to generate a forward commodity contract based on the selected optimized route, wherein the forward commodity contract is for physical delivery of the one or more geolocation exchange units.
 14. The computing system of claim 9, wherein the program instructions further comprise program instructions executable by the one or more processors to receive constraint data from the first user, wherein the constraint data indicates a selection by the first user of one or more conditions for traveling along the plurality of routes.
 15. The computing system of claim 14, wherein the program instructions further comprise program instructions executable by the one or more processors to: receive the travel cost data for the plurality of routes based on the constraint data; and receive the market depth data based on the plurality of routes and the constraint data.
 16. The computing system of claim 14, wherein the one or more conditions comprise cheapest route, single mode of transportation, multiple modes of transportation, fastest route, most scenic route, highest rated route, most available route, highest volume of participants for route, most frequent route, service level for route, highest safety and security level for route, gender of driver, security of driver, and rating of driver.
 17. A non-transitory computer-readable medium having stored thereon a plurality of computer-executable instructions which, when executed by a computer, cause the computer to: receive origin location data and destination location data from a first user, wherein the origin location data corresponds to a geographic origin and the destination location data corresponds to a geographic destination; generate a plurality of routes based on the origin location data and the destination location data; determine a plurality of virtual hubs along the plurality of routes, wherein the plurality of virtual hubs comprises a first virtual hub based on the origin location data and a second virtual hub based on the destination location data; receive travel cost data for the plurality of routes for one or more geolocation exchange units, wherein the one or more geolocation exchange units corresponds to a predetermined space traveling from the first virtual hub to the second virtual hub, and wherein the travel cost data comprises data relating to travel time, travel expenses, or combinations thereof; receive market depth data for a geolocation exchange for the one or more geolocation exchange units based on the plurality of routes, wherein the market depth data comprises one or more bid prices and one or more offer prices for the one or more geolocation exchange units; and select an optimized route of the plurality of routes for the one or more geolocation exchange units based on an objective function, wherein the objective function uses the travel cost data, the market depth data, or combinations thereof.
 18. The non-transitory computer-readable medium of claim 17, wherein the objective function comprises a function configured to minimize tolling over road space, air space, shipping space, waterborne space, travel time, travel expenses, cost of bid prices, or combinations thereof.
 19. The non-transitory computer-readable medium of claim 17, wherein the optimized route comprises a route for travel for the one or more geolocation exchange units using one or more transportation vehicles, wherein the one or more transportation vehicles comprise an automobile, an aircraft, an autonomous vehicle, a motorcycle, a drone, an unmanned aircraft, a bicycle, a boat, a bus, a subway car, a taxicab, a train, or a delivery vehicle.
 20. The non-transitory computer-readable medium of claim 17, the predetermined space comprises a seat or cargo capacity in one or more vehicles traveling from the first virtual hub to the second virtual hub. 